def calculateClusterCentre(Config, ClusterStationList):
newClusterVector = []
cfg = ConfigObj(dict=Config)
for i in range(1, cfg.Int('maxcluster') + 1):
sumlat = 0
sumlon = 0
clusterstationcounter = 0
for j in ClusterStationList:
if i == j.member:
sumlat += float(j.lat)
sumlon += float(j.lon)
clusterstationcounter += 1
#endfor
if clusterstationcounter == 0: # hs-1
newClusterVector.append(Centroid(0.0, 0.0, -1)) # hs-1
else: # hs-1
scla = sumlat / clusterstationcounter
sclo = sumlon / clusterstationcounter
name = i
newClusterVector.append(Centroid(scla, sclo, name))
return newClusterVector
def processLoop():
#==================================get meta info==========================================
C = config.Config(evpath)
Origin = C.parseConfig('origin')
try:
Syn_in = C.parseConfig('syn')
syn_in = SynthCfg(Syn_in)
except:
pass
Config = C.parseConfig('config')
cfg = ConfigObj(dict=Config)
if cfg.pyrocko_download() == True:
Meta = C.readpyrockostations() #
elif cfg.colesseo_input() == True:
scenario = guts.load(filename=cfg.colosseo_scenario_yml())
scenario_path = cfg.colosseo_scenario_yml()[:-12]
Meta = C.readcolosseostations(scenario_path)
else:
Meta = C.readMetaInfoFile()
#==================================get meta info==========================================
#==================================do prerequiries========================================
Folder = C.createFolder()
#C.cpSkeleton(Folder,Config)
C.writeConfig(Config, Origin, Folder)
filter = FilterCfg(Config)
ntimes = int(
(cfg.UInt('forerun') + cfg.UInt('duration')) / cfg.UInt('step'))
origin = OriginCfg(Origin)
if cfg.colesseo_input() == True:
from pyrocko import util
events = scenario.get_events()
ev = events[0]
origin.strike = str(ev.moment_tensor.strike1)
origin.rake = str(ev.moment_tensor.rake1)
origin.dip = str(ev.moment_tensor.dip1)
strike = ev.moment_tensor.strike1
origin.lat = str(ev.lat)
origin.lon = str(ev.lon)
origin.depth = str(ev.depth / 1000.)
depth = ev.depth
origin.time = util.time_to_str(ev.time)
time_ev = util.time_to_str(ev.time)
lat = ev.lat
lon = ev.lon
rake = ev.moment_tensor.rake1
dip = ev.moment_tensor.dip1
Origin['strike'] = str(ev.moment_tensor.strike1)
Origin['rake'] = str(ev.moment_tensor.rake1)
Origin['dip'] = str(ev.moment_tensor.dip1)
Origin['lat'] = str(ev.lat)
Origin['lon'] = str(ev.lon)
Origin['time'] = util.time_to_str(ev.time)
Origin['depth'] = str(ev.depth / 1000.)
ev = Event(lat, lon, depth, time_ev, strike=strike, dip=dip, rake=rake)
else:
default = 0
strike = origin.strike(default) # Origin.get ('strike', default)
dip = origin.dip(default) # Origin.get ('dip', default)
rake = origin.rake(default) # Origin.get ('rake', default)
ev = Event(origin.lat(),
origin.lon(),
origin.depth(),
origin.time(),
strike=strike,
dip=dip,
rake=rake)
filtername = filter.filterName()
Logfile.add('filtername = ' + filtername)
#todo crosscorrelation for all arrays before processing
XDict = {}
RefDict = {}
SL = {}
if cfg.Int('xcorr') == 1:
newFreq = str(filter.newFrequency())
fobjreferenceshiftname = newFreq + '_' + filtername + '.refpkl'
rp = os.path.join(Folder['semb'], fobjreferenceshiftname)
fobjpickleshiftname = newFreq + '_' + filtername + '.xcorrpkl'
ps = os.path.join(Folder['semb'], fobjpickleshiftname)
if (os.path.isfile(rp) and os.path.getsize(rp) != 0
and os.path.isfile(ps) and os.path.getsize(ps) != 0):
Logfile.add('file exits : ' + rp)
Logfile.add('load refshifts')
f = open(rp)
RefDict = pickle.load(f)
x = open(ps)
XDict = pickle.load(x)
xcorrnetworks = cfg.String('networks').split(',')
for i in xcorrnetworks:
SL[i] = len(Config[i].split('|'))
else:
SL = {}
xcorrnetworks = cfg.String('networks').split(',')
for i in xcorrnetworks:
W = {}
refshift = 0
network = cfg.String(i).split('|')
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
arrayfolder = os.path.join(Folder['semb'], i)
if os.access(arrayfolder, os.F_OK) == False:
os.makedirs(arrayfolder)
if cfg.pyrocko_download() == True:
A = Xcorr(ev, FilterMeta, evpath, Config, Syn_in,
arrayfolder)
else:
A = Xcorr(ev, FilterMeta, evpath, Config, Syn_in,
arrayfolder)
print "run Xcorr"
W, triggerobject = A.runXcorr()
XDict[i] = W
RefDict[i] = triggerobject.tdiff
SL[i] = len(network)
#endfor
fobjrefshift = open(rp, 'w')
pickle.dump(RefDict, fobjrefshift)
fobjrefshift.close()
output = open(ps, 'w')
pickle.dump(XDict, output)
output.close()
for i in sorted(XDict.iterkeys()):
Logfile.red('Array %s has %3d of %3d Stations left' %
(i, len(XDict[i]), SL[i]))
logger.info(
'\033[31mFor proceeding without changes press enter or give new comma seperatet network list or quit for exit\033[0m'
)
while True:
nnl = raw_input("please enter your choice: ")
#Logfile.add ('Choise = ' + nnl)
if len(nnl) == 0:
if not Basic.question('Process all networks ?'): continue
Logfile.red('This networks will be used for processing: %s' %
(Config['networks']))
break
elif str(nnl) == 'quit':
sys.exit()
elif str(nnl) == 'rerun':
event = os.path.join(*evpath.split('/')[-1:])
try:
os.remove(rp)
os.remove(ps)
except:
pass
mainfolder = os.path.join(os.path.sep, *evpath.split('/')[:-2])
os.chdir(mainfolder)
cmd = ('%s arraytool.py process %s') % (sys.executable, event)
Logfile.add('cmd = ' + cmd)
os.system(cmd)
sys.exit()
else:
# Check if selected array(s) exists
names = nnl.split(',')
isOk = True
for array in names:
arrayfolder = os.path.join(Folder['semb'], array)
if not os.path.isdir(arrayfolder):
Logfile.error('Illegal network name ' + str(array))
isOk = False
break
#endfor
if not isOk: continue # Illegal network : input again
# use these networks
Logfile.add('This networks will be used for processing: %s' %
(nnl))
Config['networks'] = nnl
break
for i in range(3, 0, -1):
time.sleep(1)
Logfile.red('Start processing in %d seconds ' % (i))
wd = Origin['depth']
start, stop, step = cfg.String('depths').split(',')
start = int(start)
stop = int(stop) + 1
step = int(step)
filters = cfg.String('filters')
filters = int(filters)
Logfile.add('working on ' + Config['networks'])
#==================================loop over depth======================
for filterindex in xrange(0, filters):
for depthindex in xrange(start, stop, step):
workdepth = float(wd) + depthindex
Origin['depth'] = workdepth
ev = Event(Origin['lat'],
Origin['lon'],
Origin['depth'],
Origin['time'],
strike=strike,
dip=dip,
rake=rake)
Logfile.add('WORKDEPTH: ' + str(Origin['depth']))
#==================================do prerequiries===============
#==================================loop over arrays================
ASL = []
weights = []
array_centers = []
networks = Config['networks'].split(',')
counter = 1
TriggerOnset = []
Wdfs = []
for i in networks:
arrayname = i
arrayfolder = os.path.join(Folder['semb'], arrayname)
network = Config[i].split('|')
Logfile.add('network: ' + str(network))
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
#if len(FilterMeta) < 3: continue #hs : wieder rein
if len(FilterMeta) < 3: continue
W = XDict[i]
refshift = RefDict[i]
FilterMeta = cmpFilterMetavsXCORR(W, FilterMeta)
Logfile.add(
'BOUNDING BOX DIMX: %s DIMY: %s GRIDSPACING: %s \n' %
(Config['dimx'], Config['dimy'], Config['gridspacing']))
##############=======================PARALLEL===========================================
Logfile.red('Calculating Traveltime Grid')
t1 = time.time()
isParallel = False #10.12.2015
TTTGridMap = []
mint = []
maxt = []
try:
f = open(
'../tttgrid/tttgrid_%s_%s_%s.pkl' %
(ev.time, arrayname, workdepth), 'rb')
print "loading travel time grid_%s_%s_%s.pkl" % (
ev.time, arrayname, workdepth)
TTTGridMap, mint, maxt = pickle.load(f)
f.close()
print "loading of travel time grid sucessful"
except:
print "loading of travel time grid unsucessful, will now calculate the grid:"
if isParallel: #hs
# maxp = int (Config['ncore'])
maxp = 6 #hs
po = multiprocessing.Pool(maxp)
for i in xrange(len(FilterMeta)):
po.apply_async(ttt.calcTTTAdv,
(Config, FilterMeta[i], Origin, i,
arrayname, W, refshift))
po.close()
po.join()
else: #hs+
for i in xrange(len(FilterMeta)):
t1 = time.time()
ttt.calcTTTAdv(Config, FilterMeta[i], Origin, i,
arrayname, W, refshift)
Logfile.add('ttt.calcTTTAdv : ' +
str(time.time() - t1) + ' sec.')
#endif #hs-
assert len(FilterMeta) > 0
TTTGridMap = deserializer.deserializeTTT(len(FilterMeta))
mint, maxt = deserializer.deserializeMinTMaxT(
len(FilterMeta))
f = open(
'../tttgrid/tttgrid_%s_%s_%s.pkl' %
(ev.time, arrayname, workdepth), 'wb')
print "dumping the traveltime grid for this array"
pickle.dump([TTTGridMap, mint, maxt], f)
f.close()
t2 = time.time()
Logfile.red('%s took %0.3f s' % ('TTT', (t2 - t1)))
switch = filterindex
tw = times.calculateTimeWindows(mint, maxt, Config, ev, switch)
if cfg.pyrocko_download() == True:
if cfg.quantity() == 'displacement':
Wd = waveform.readWaveformsPyrocko_restituted(
FilterMeta, tw, evpath, ev)
else:
Wd = waveform.readWaveformsPyrocko(
FilterMeta, tw, evpath, ev)
# Wdf = waveform.processpyrockoWaveforms(Wd, Config, Folder, arrayname, FilterMeta, ev, switch, W)
elif cfg.colesseo_input() == True:
Wd = waveform.readWaveforms_colesseo(
FilterMeta, tw, evpath, ev, C)
else:
Wd = waveform.readWaveforms(FilterMeta, tw, evpath, ev)
if cfg.Bool('synthetic_test') is True:
Wdf = waveform.processdummyWaveforms(
Wd, Config, Folder, arrayname, FilterMeta, ev, switch,
W)
Wdfs.append(Wdf)
else:
Wdf = waveform.processWaveforms(Wd, Config, Folder,
arrayname, FilterMeta, ev,
switch, W)
Wdfs.append(Wdf)
C.writeStationFile(FilterMeta, Folder, counter)
Logfile.red('%d Streams added for Processing' % (len(Wd)))
t1 = time.time()
f = open(
'../tttgrid/tttgrid_%s_%s_%s.pkl' %
(ev.time, arrayname, workdepth), 'rb')
print "loading travel time grid_%s_%s_%s.pkl" % (
ev.time, arrayname, workdepth)
TTTGridMap, mint, maxt = pickle.load(f)
f.close()
if cfg.optimize() == True:
optim.solve(counter, Config, Wdf, FilterMeta, mint, maxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev,
arrayfolder, syn_in)
else:
arraySemb, weight, array_center = sembCalc.doCalc(
counter, Config, Wdf, FilterMeta, mint, maxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev,
arrayfolder, syn_in)
t2 = time.time()
Logfile.add('CALC took %0.3f sec' % (t2 - t1))
weights.append(weight)
array_centers.append(array_center)
ASL.append(arraySemb)
counter += 1
sembCalc.writeSembMatricesSingleArray(arraySemb, Config,
Origin, arrayfolder,
ntimes, switch)
fileName = os.path.join(arrayfolder, 'stations.txt')
Logfile.add('Write to file ' + fileName)
fobjarraynetwork = open(fileName, 'w')
for i in FilterMeta:
fobjarraynetwork.write(
('%s %s %s\n') % (i.getName(), i.lat, i.lon))
fobjarraynetwork.close()
TTTGridMAP = []
if cfg.optimize_all() == True:
import optim_csemb
from optim_csemb import solve
sembmax = sembCalc.collectSemb(ASL, Config, Origin, Folder,
ntimes, len(networks), switch)
optim_csemb.solve(counter, Config, Wdf, FilterMeta, mint, maxt,
TTTGridMap, Folder, Origin, ntimes, switch,
ev, arrayfolder, syn_in, ASL, sembmax,
evpath, XDict, RefDict, workdepth,
filterindex, Wdfs)
if ASL:
Logfile.red('collect semblance matrices from all arrays')
sembmax = sembCalc.collectSemb(ASL, Config, Origin, Folder,
ntimes, len(networks), switch,
array_centers)
if cfg.Bool('weight_by_noise') == True:
sembCalc.collectSembweighted(ASL, Config, Origin, Folder,
ntimes, len(networks), switch,
weights)
else:
Logfile.red('Nothing to do -> Finish')
print "depth:"
print workdepth
def doCalc(flag, Config, WaveformDict, FilterMetaData, Gmint, Gmaxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev, arrayfolder,
syn_in):
'''
method for calculating semblance of one station array
'''
Logfile.add('PROCESS %d %s' % (flag, ' Enters Semblance Calculation'))
Logfile.add('MINT : %f MAXT: %f Traveltime' % (Gmint, Gmaxt))
cfg = ConfigObj(dict=Config)
dimX = cfg.dimX() # ('dimx')
dimY = cfg.dimY() # ('dimy')
winlen = cfg.winlen() # ('winlen')
step = cfg.step() # ('step')
new_frequence = cfg.newFrequency() #('new_frequence')
forerun = cfg.Int('forerun')
duration = cfg.Int('duration')
gridspacing = cfg.Float('gridspacing')
nostat = len(WaveformDict)
traveltimes = {}
recordstarttime = ''
minSampleCount = 999999999
ntimes = int((forerun + duration) / step)
nsamp = int(winlen * new_frequence)
nstep = int(step * new_frequence)
from pyrocko import obspy_compat
from pyrocko import orthodrome, model
obspy_compat.plant()
############################################################################
calcStreamMap = WaveformDict
stations = []
py_trs = []
for trace in calcStreamMap.iterkeys():
py_tr = obspy_compat.to_pyrocko_trace(calcStreamMap[trace])
py_trs.append(py_tr)
for il in FilterMetaData:
if str(il) == str(trace):
szo = model.Station(lat=il.lat,
lon=il.lon,
station=il.sta,
network=il.net,
channels=py_tr.channel,
elevation=il.ele,
location=il.loc)
stations.append(szo) #right number of stations?
#==================================synthetic BeamForming=======================================
if cfg.Bool('shift_by_phase_pws') == True:
calcStreamMapshifted = calcStreamMap.copy()
from obspy.core import stream
stream = stream.Stream()
for trace in calcStreamMapshifted.iterkeys():
stream.append(calcStreamMapshifted[trace])
pws_stack = PWS_stack([stream], weight=2, normalize=True)
for tr in pws_stack:
for trace in calcStreamMapshifted.iterkeys():
calcStreamMapshifted[trace] = tr
calcStreamMap = calcStreamMapshifted
if cfg.Bool('shift_by_phase_onset') == True:
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
for trace in calcStreamMapshifted.iterkeys():
recordstarttime = calcStreamMapshifted[
trace].stats.starttime.timestamp
recordendtime = calcStreamMapshifted[trace].stats.endtime.timestamp
mod = shifted_traces[i]
extracted = mod.chop(recordstarttime, recordendtime, inplace=False)
shifted_obs_tr = obspy_compat.to_obspy_trace(extracted)
calcStreamMapshifted[trace] = shifted_obs_tr
i = i + 1
calcStreamMap = calcStreamMapshifted
weight = 0.
if cfg.Bool('weight_by_noise') == True:
from noise_analyser import analyse
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
weight = analyse(shifted_traces,
engine,
event,
stations,
100.,
store_id,
nwindows=1,
check_events=True,
phase_def='P')
for trace in calcStreamMap.iterkeys():
recordstarttime = calcStreamMap[trace].stats.starttime
d = calcStreamMap[trace].stats.starttime
d = d.timestamp
if calcStreamMap[trace].stats.npts < minSampleCount:
minSampleCount = calcStreamMap[trace].stats.npts
############################################################################
traces = num.ndarray(shape=(len(calcStreamMap), minSampleCount),
dtype=float)
traveltime = num.ndarray(shape=(len(calcStreamMap), dimX * dimY),
dtype=float)
latv = num.ndarray(dimX * dimY, dtype=float)
lonv = num.ndarray(dimX * dimY, dtype=float)
############################################################################
c = 0
streamCounter = 0
for key in calcStreamMap.iterkeys():
streamID = key
c2 = 0
for o in calcStreamMap[key]:
if c2 < minSampleCount:
traces[c][c2] = o
c2 += 1
for key in TTTGridMap.iterkeys():
if streamID == key:
traveltimes[streamCounter] = TTTGridMap[key]
else:
"NEIN", streamID, key
if not streamCounter in traveltimes:
continue #hs : thread crashed before
g = traveltimes[streamCounter]
dimZ = g.dimZ
mint = g.mint
maxt = g.maxt
Latul = g.Latul
Lonul = g.Lonul
Lator = g.Lator
Lonor = g.Lonor
gridElem = g.GridArray
for x in range(dimX):
for y in range(dimY):
elem = gridElem[x, y]
traveltime[c][x * dimY + y] = elem.tt
latv[x * dimY + y] = elem.lat
lonv[x * dimY + y] = elem.lon
#endfor
c += 1
streamCounter += 1
#endfor
############################## CALCULATE PARAMETER FOR SEMBLANCE CALCULATION ##################
nsamp = winlen * new_frequence
nstep = int(step * new_frequence)
migpoints = dimX * dimY
dimZ = 0
new_frequence = cfg.newFrequency() # ['new_frequence']
maxp = int(Config['ncore'])
Logfile.add('PROCESS %d NTIMES: %d' % (flag, ntimes))
if False:
print('nostat ', nostat, type(nostat))
print('nsamp ', nsamp, type(nsamp))
print('ntimes ', ntimes, type(ntimes))
print('nstep ', nstep, type(nstep))
print('dimX ', dimX, type(dimX))
print('dimY ', dimY, type(dimY))
print('mint ', Gmint, type(mint))
print('new_freq ', new_frequence, type(new_frequence))
print('minSampleCount ', minSampleCount, type(minSampleCount))
print('latv ', latv, type(latv))
print('traces', traces, type(traces))
print('traveltime', traveltime, type(traveltime))
t1 = time.time()
traces_org = traces.reshape(1, nostat * minSampleCount)
traveltime_org = traveltime.reshape(1, nostat * dimX * dimY)
USE_C_CODE = True
try:
if USE_C_CODE:
import Cm
import CTrig
start_time = time.time()
k = Cm.otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv,
traveltime_org, traces_org)
print("--- %s seconds ---" % (time.time() - start_time))
else:
start_time = time.time()
k = otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv,
traveltime_org, traces_org) #hs
print("--- %s seconds ---" % (time.time() - start_time))
except:
print "loaded tttgrid has probably wrong dimensions or stations, delete\
ttgrid or exchange"
t2 = time.time()
Logfile.add('%s took %0.3f s' % ('CALC:', (t2 - t1)))
partSemb = k
partSemb_data = partSemb.reshape(ntimes, migpoints)
return partSemb_data
def doCalc_syn(flag, Config, WaveformDict, FilterMetaData, Gmint, Gmaxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev, arrayfolder,
syn_in, parameter):
'''
method for calculating semblance of one station array
'''
Logfile.add('PROCESS %d %s' % (flag, ' Enters Semblance Calculation'))
Logfile.add('MINT : %f MAXT: %f Traveltime' % (Gmint, Gmaxt))
cfg = ConfigObj(dict=Config)
dimX = cfg.dimX() # ('dimx')
dimY = cfg.dimY() # ('dimy')
winlen = cfg.winlen() # ('winlen')
step = cfg.step() # ('step')
new_frequence = cfg.newFrequency() #('new_frequence')
forerun = cfg.Int('forerun')
duration = cfg.Int('duration')
gridspacing = cfg.Float('gridspacing')
nostat = len(WaveformDict)
traveltimes = {}
recordstarttime = ''
minSampleCount = 999999999
ntimes = int((forerun + duration) / step)
nsamp = int(winlen * new_frequence)
nstep = int(step * new_frequence)
from pyrocko import obspy_compat
from pyrocko import orthodrome, model
obspy_compat.plant()
############################################################################
calcStreamMap = WaveformDict
stations = []
py_trs = []
for trace in calcStreamMap.iterkeys():
py_tr = obspy_compat.to_pyrocko_trace(calcStreamMap[trace])
py_trs.append(py_tr)
for il in FilterMetaData:
if str(il) == str(trace):
szo = model.Station(lat=il.lat,
lon=il.lon,
station=il.sta,
network=il.net,
channels=py_tr.channel,
elevation=il.ele,
location=il.loc)
stations.append(szo) #right number of stations?
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
targets = []
for st in stations:
target = Target(lat=st.lat,
lon=st.lon,
store_id=store_id,
codes=(st.network, st.station, st.location, 'BHZ'),
tmin=-1900,
tmax=3900,
interpolation='multilinear',
quantity=cfg.quantity())
targets.append(target)
if syn_in.nsources() == 1:
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
source = RectangularSource(
lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
depth=syn_in.depth_syn_0() * 1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
width=syn_in.width_0() * 1000.,
length=syn_in.length_0() * 1000.,
nucleation_x=syn_in.nucleation_x_0(),
slip=syn_in.slip_0(),
nucleation_y=syn_in.nucleation_y_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0()))
if syn_in.source() == 'DCSource':
source = DCSource(lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
depth=syn_in.depth_syn_0() * 1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0()),
magnitude=syn_in.magnitude_0())
else:
sources = []
for i in range(syn_in.nsources()):
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
sources.append(
RectangularSource(
lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
depth=syn_in.depth_syn_1(i) * 1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
width=syn_in.width_1(i) * 1000.,
length=syn_in.length_1(i) * 1000.,
nucleation_x=syn_in.nucleation_x_1(i),
slip=syn_in.slip_1(i),
nucleation_y=syn_in.nucleation_y_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i))))
if syn_in.source() == 'DCSource':
sources.append(
DCSource(lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
depth=syn_in.depth_1(i) * 1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i)),
magnitude=syn_in.magnitude_1(i)))
source = CombiSource(subsources=sources)
response = engine.process(source, targets)
synthetic_traces = response.pyrocko_traces()
if cfg.Bool('synthetic_test_add_noise') is True:
from noise_addition import add_noise
trs_orgs = []
calcStreamMapsyn = calcStreamMap.copy()
#from pyrocko import trace
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12]) == str(tracex[4:]):
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapsyn[tracex])
tr_org.downsample_to(2.0)
trs_orgs.append(tr_org)
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
synthetic_traces = add_noise(trs_orgs,
engine,
source.pyrocko_event(),
stations,
store_id,
phase_def='P')
trs_org = []
trs_orgs = []
fobj = os.path.join(arrayfolder, 'shift.dat')
xy = num.loadtxt(fobj, usecols=1, delimiter=',')
calcStreamMapsyn = calcStreamMap.copy()
#from pyrocko import trace
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12]) == str(tracex[4:]):
mod = trl
recordstarttime = calcStreamMapsyn[
tracex].stats.starttime.timestamp
recordendtime = calcStreamMapsyn[
tracex].stats.endtime.timestamp
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapsyn[tracex])
trs_orgs.append(tr_org)
tr_org_add = mod.chop(recordstarttime,
recordendtime,
inplace=False)
synthetic_obs_tr = obspy_compat.to_obspy_trace(tr_org_add)
calcStreamMapsyn[tracex] = synthetic_obs_tr
trs_org.append(tr_org_add)
calcStreamMap = calcStreamMapsyn
if cfg.Bool('shift_by_phase_pws') == True:
calcStreamMapshifted = calcStreamMap.copy()
from obspy.core import stream
stream = stream.Stream()
for trace in calcStreamMapshifted.iterkeys():
stream.append(calcStreamMapshifted[trace])
pws_stack = PWS_stack([stream], weight=2, normalize=True)
for tr in pws_stack:
for trace in calcStreamMapshifted.iterkeys():
calcStreamMapshifted[trace] = tr
calcStreamMap = calcStreamMapshifted
if cfg.Bool('shift_by_phase_onset') == True:
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
for trace in calcStreamMapshifted.iterkeys():
recordstarttime = calcStreamMapshifted[
trace].stats.starttime.timestamp
recordendtime = calcStreamMapshifted[trace].stats.endtime.timestamp
mod = shifted_traces[i]
extracted = mod.chop(recordstarttime, recordendtime, inplace=False)
shifted_obs_tr = obspy_compat.to_obspy_trace(extracted)
calcStreamMapshifted[trace] = shifted_obs_tr
i = i + 1
calcStreamMap = calcStreamMapshifted
weight = 0.
if cfg.Bool('weight_by_noise') == True:
from noise_analyser import analyse
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
weight = analyse(shifted_traces,
engine,
event,
stations,
100.,
store_id,
nwindows=1,
check_events=True,
phase_def='P')
for trace in calcStreamMap.iterkeys():
recordstarttime = calcStreamMap[trace].stats.starttime
d = calcStreamMap[trace].stats.starttime
d = d.timestamp
if calcStreamMap[trace].stats.npts < minSampleCount:
minSampleCount = calcStreamMap[trace].stats.npts
############################################################################
traces = num.ndarray(shape=(len(calcStreamMap), minSampleCount),
dtype=float)
traveltime = num.ndarray(shape=(len(calcStreamMap), dimX * dimY),
dtype=float)
latv = num.ndarray(dimX * dimY, dtype=float)
lonv = num.ndarray(dimX * dimY, dtype=float)
############################################################################
c = 0
streamCounter = 0
for key in calcStreamMap.iterkeys():
streamID = key
c2 = 0
for o in calcStreamMap[key]:
if c2 < minSampleCount:
traces[c][c2] = o
c2 += 1
for key in TTTGridMap.iterkeys():
if streamID == key:
traveltimes[streamCounter] = TTTGridMap[key]
else:
"NEIN", streamID, key
if not streamCounter in traveltimes:
continue #hs : thread crashed before
g = traveltimes[streamCounter]
dimZ = g.dimZ
mint = g.mint
maxt = g.maxt
Latul = g.Latul
Lonul = g.Lonul
Lator = g.Lator
Lonor = g.Lonor
gridElem = g.GridArray
for x in range(dimX):
for y in range(dimY):
elem = gridElem[x, y]
traveltime[c][x * dimY + y] = elem.tt
latv[x * dimY + y] = elem.lat
lonv[x * dimY + y] = elem.lon
#endfor
c += 1
streamCounter += 1
#endfor
############################## CALCULATE PARAMETER FOR SEMBLANCE CALCULATION ##################
nsamp = winlen * new_frequence
nstep = int(step * new_frequence)
migpoints = dimX * dimY
dimZ = 0
new_frequence = cfg.newFrequency() # ['new_frequence']
maxp = int(Config['ncore'])
Logfile.add('PROCESS %d NTIMES: %d' % (flag, ntimes))
if False:
print('nostat ', nostat, type(nostat))
print('nsamp ', nsamp, type(nsamp))
print('ntimes ', ntimes, type(ntimes))
print('nstep ', nstep, type(nstep))
print('dimX ', dimX, type(dimX))
print('dimY ', dimY, type(dimY))
print('mint ', Gmint, type(mint))
print('new_freq ', new_frequence, type(new_frequence))
print('minSampleCount ', minSampleCount, type(minSampleCount))
print('latv ', latv, type(latv))
print('traces', traces, type(traces))
print('traveltime', traveltime, type(traveltime))
#==================================semblance calculation========================================
t1 = time.time()
traces = traces.reshape(1, nostat * minSampleCount)
traveltime = traveltime.reshape(1, nostat * dimX * dimY)
USE_C_CODE = True
try:
if USE_C_CODE:
import Cm
import CTrig
start_time = time.time()
k = Cm.otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltime,
traces)
print("--- %s seconds ---" % (time.time() - start_time))
else:
start_time = time.time()
k = otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltime,
traces) #hs
print("--- %s seconds ---" % (time.time() - start_time))
except:
print "loaded tttgrid has probably wrong dimensions or stations, delete\
ttgrid or exchange"
t2 = time.time()
partSemb = k
partSemb_syn = partSemb.reshape(ntimes, migpoints)
return partSemb_syn
def doCalc(flag, Config, WaveformDict, FilterMetaData, Gmint, Gmaxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev, arrayfolder,
syn_in):
'''
method for calculating semblance of one station array
'''
Logfile.add('PROCESS %d %s' % (flag, ' Enters Semblance Calculation'))
Logfile.add('MINT : %f MAXT: %f Traveltime' % (Gmint, Gmaxt))
cfg = ConfigObj(dict=Config)
cfg_f = FilterCfg(Config)
timeev = util.str_to_time(ev.time)
dimX = cfg.dimX() #('dimx')
dimY = cfg.dimY() #('dimy')
winlen = cfg.winlen() #('winlen')
step = cfg.step() #('step')
new_frequence = cfg.newFrequency() #('new_frequence')
forerun = cfg.Int('forerun')
duration = cfg.Int('duration')
nostat = len(WaveformDict)
traveltimes = {}
recordstarttime = ''
minSampleCount = 999999999
ntimes = int((forerun + duration) / step)
nsamp = int(winlen * new_frequence)
nstep = int(step * new_frequence)
from pyrocko import obspy_compat
from pyrocko import model
obspy_compat.plant()
############################################################################
calcStreamMap = WaveformDict
stations = []
py_trs = []
lats = []
lons = []
for trace in calcStreamMap.iterkeys():
py_tr = obspy_compat.to_pyrocko_trace(calcStreamMap[trace])
py_trs.append(py_tr)
for il in FilterMetaData:
if str(il) == str(trace):
szo = model.Station(lat=float(il.lat),
lon=float(il.lon),
station=il.sta,
network=il.net,
channels=py_tr.channel,
elevation=il.ele,
location=il.loc)
stations.append(szo)
lats.append(float(il.lat))
lons.append(float(il.lon))
array_center = [num.mean(lats), num.mean(lons)]
#==================================synthetic BeamForming======================
if cfg.Bool('synthetic_test') is True:
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
recordstarttimes = []
for tracex in calcStreamMap.iterkeys():
recordstarttimes.append(
calcStreamMap[tracex].stats.starttime.timestamp)
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMap[tracex])
tmin = tr_org.tmin
#tmin= num.min(recordstarttimes)
targets = []
sources = []
for st in stations:
target = Target(lat=st.lat,
lon=st.lon,
store_id=store_id,
codes=(st.network, st.station, st.location, 'BHZ'),
tmin=-6900,
tmax=6900,
interpolation='multilinear',
quantity=cfg.quantity())
targets.append(target)
if syn_in.nsources() == 1:
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
sources.append(
RectangularSource(
lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
east_shift=float(syn_in.east_shift_0()) * 1000.,
north_shift=float(syn_in.north_shift_0()) * 1000.,
depth=syn_in.depth_syn_0() * 1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
width=syn_in.width_0() * 1000.,
length=syn_in.length_0() * 1000.,
nucleation_x=syn_in.nucleation_x_0(),
slip=syn_in.slip_0(),
nucleation_y=syn_in.nucleation_y_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0())))
if syn_in.source() == 'DCSource':
sources.append(
DCSource(lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
east_shift=float(syn_in.east_shift_0()) * 1000.,
north_shift=float(syn_in.north_shift_0()) * 1000.,
depth=syn_in.depth_syn_0() * 1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0()),
magnitude=syn_in.magnitude_0()))
else:
for i in range(syn_in.nsources()):
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
sources.append(
RectangularSource(
lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
east_shift=float(syn_in.east_shift_1(i)) * 1000.,
north_shift=float(syn_in.north_shift_1(i)) * 1000.,
depth=syn_in.depth_syn_1(i) * 1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
width=syn_in.width_1(i) * 1000.,
length=syn_in.length_1(i) * 1000.,
nucleation_x=syn_in.nucleation_x_1(i),
slip=syn_in.slip_1(i),
nucleation_y=syn_in.nucleation_y_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i))))
if syn_in.source() == 'DCSource':
sources.append(
DCSource(
lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
east_shift=float(syn_in.east_shift_1(i)) * 1000.,
north_shift=float(syn_in.north_shift_1(i)) * 1000.,
depth=syn_in.depth_syn_1(i) * 1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i)),
magnitude=syn_in.magnitude_1(i)))
#source = CombiSource(subsources=sources)
synthetic_traces = []
for source in sources:
response = engine.process(source, targets)
synthetic_traces_source = response.pyrocko_traces()
if not synthetic_traces:
synthetic_traces = synthetic_traces_source
else:
for trsource, tr in zip(synthetic_traces_source,
synthetic_traces):
tr.add(trsource)
from pyrocko import trace as trld
#trld.snuffle(synthetic_traces)
timeev = util.str_to_time(syn_in.time_0())
if cfg.Bool('synthetic_test_add_noise') is True:
from noise_addition import add_noise
trs_orgs = []
calcStreamMapsyn = calcStreamMap.copy()
#from pyrocko import trace
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12]) == str(tracex[4:]) or str(
trl.name()[3:13]) == str(tracex[3:]) or str(
trl.name()[3:11]) == str(tracex[3:]) or str(
trl.name()[3:14]) == str(tracex[3:]):
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapsyn[tracex])
tr_org.downsample_to(2.0)
trs_orgs.append(tr_org)
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
synthetic_traces = add_noise(trs_orgs,
engine,
source.pyrocko_event(),
stations,
store_id,
phase_def='P')
trs_org = []
trs_orgs = []
from pyrocko import trace
fobj = os.path.join(arrayfolder, 'shift.dat')
calcStreamMapsyn = calcStreamMap.copy()
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12]) == str(tracex[4:]) or str(
trl.name()[3:13]) == str(tracex[3:]) or str(
trl.name()[3:11]) == str(tracex[3:]) or str(
trl.name()[3:14]) == str(tracex[3:]):
mod = trl
recordstarttime = calcStreamMapsyn[
tracex].stats.starttime.timestamp
recordendtime = calcStreamMapsyn[
tracex].stats.endtime.timestamp
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapsyn[tracex])
if switch == 0:
tr_org.bandpass(4, cfg_f.flo(), cfg_f.fhi())
elif switch == 1:
tr_org.bandpass(4, cfg_f.flo2(), cfg_f.fhi2())
trs_orgs.append(tr_org)
tr_org_add = mod.chop(recordstarttime,
recordendtime,
inplace=False)
synthetic_obs_tr = obspy_compat.to_obspy_trace(tr_org_add)
calcStreamMapsyn[tracex] = synthetic_obs_tr
trs_org.append(tr_org_add)
calcStreamMap = calcStreamMapsyn
if cfg.Bool('shift_by_phase_pws') == True:
calcStreamMapshifted = calcStreamMap.copy()
from obspy.core import stream
stream = stream.Stream()
for trace in calcStreamMapshifted.iterkeys():
stream.append(calcStreamMapshifted[trace])
pws_stack = PWS_stack([stream], weight=2, normalize=True)
for tr in pws_stack:
for trace in calcStreamMapshifted.iterkeys():
calcStreamMapshifted[trace] = tr
calcStreamMap = calcStreamMapshifted
if cfg.Bool('shift_by_phase_cc') is True:
from stacking import align_traces
calcStreamMapshifted = calcStreamMap.copy()
list_tr = []
for trace in calcStreamMapshifted.iterkeys():
tr_org = calcStreamMapshifted[trace]
list_tr.append(tr_org)
shifts, ccs = align_traces(list_tr, 10, master=False)
for shift in shifts:
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapshifted[trace])
tr_org.shift(shift)
shifted = obspy_compat.to_obspy_trace(tr_org)
calcStreamMapshifted[trace] = shifted
calcStreamMap = calcStreamMapshifted
if cfg.Bool('shift_by_phase_onset') is True:
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
for tracex in calcStreamMapshifted.iterkeys():
for trl in shifted_traces:
if str(trl.name()[4:12]) == str(tracex[4:]) or str(
trl.name()[3:13]) == str(tracex[3:]) or str(
trl.name()[3:11]) == str(tracex[3:]) or str(
trl.name()[3:14]) == str(tracex[3:]):
mod = trl
recordstarttime = calcStreamMapshifted[
tracex].stats.starttime.timestamp
recordendtime = calcStreamMapshifted[
tracex].stats.endtime.timestamp
tr_org = obspy_compat.to_pyrocko_trace(
calcStreamMapshifted[tracex])
tr_org_add = mod.chop(recordstarttime,
recordendtime,
inplace=False)
shifted_obs_tr = obspy_compat.to_obspy_trace(tr_org_add)
calcStreamMapshifted[tracex] = shifted_obs_tr
calcStreamMap = calcStreamMapshifted
weight = 1.
if cfg.Bool('weight_by_noise') is True:
from noise_analyser import analyse
pjoin = os.path.join
timeev = util.str_to_time(ev.time)
trs_orgs = []
calcStreamMapshifted = calcStreamMap.copy()
for trace in calcStreamMapshifted.iterkeys():
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapshifted[trace])
trs_orgs.append(tr_org)
timing = CakeTiming(
phase_selection='first(p|P|PP|P(cmb)P(icb)P(icb)p(cmb)p)-20',
fallback_time=100.)
traces = trs_orgs
event = model.Event(lat=float(ev.lat),
lon=float(ev.lon),
depth=ev.depth * 1000.,
time=timeev)
directory = arrayfolder
bf = BeamForming(stations, traces, normalize=True)
shifted_traces = bf.process(event=event,
timing=timing,
fn_dump_center=pjoin(
directory, 'array_center.pf'),
fn_beam=pjoin(directory, 'beam.mseed'))
i = 0
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
weight = analyse(shifted_traces,
engine,
event,
stations,
100.,
store_id,
nwindows=1,
check_events=True,
phase_def='P')
if cfg.Bool('array_response') is True:
from obspy.signal import array_analysis
from obspy.core import stream
ntimesr = int((forerun + duration) / step)
nsampr = int(winlen)
nstepr = int(step)
sll_x = -3.0
slm_x = 3.0
sll_y = -3.0
slm_y = 3.0
sl_s = 0.03,
# sliding window properties
# frequency properties
frqlow = 1.0,
frqhigh = 8.0
prewhiten = 0
# restrict output
semb_thres = -1e9
vel_thres = -1e9
stime = stime
etime = etime
stream_arr = stream.Stream()
for trace in calcStreamMapshifted.iterkeys():
stream_arr.append(calcStreamMapshifted[trace])
results = array_analysis.array_processing(stream_arr, nsamp, nstep,\
sll_x, slm_x, sll_y, slm_y,\
sl_s, semb_thres, vel_thres, \
frqlow, frqhigh, stime, \
etime, prewhiten)
timestemp = results[0]
relative_relpow = results[1]
absolute_relpow = results[2]
for trace in calcStreamMap.iterkeys():
recordstarttime = calcStreamMap[trace].stats.starttime
d = calcStreamMap[trace].stats.starttime
d = d.timestamp
if calcStreamMap[trace].stats.npts < minSampleCount:
minSampleCount = calcStreamMap[trace].stats.npts
###########################################################################
traces = num.ndarray(shape=(len(calcStreamMap), minSampleCount),
dtype=float)
traveltime = num.ndarray(shape=(len(calcStreamMap), dimX * dimY),
dtype=float)
latv = num.ndarray(dimX * dimY, dtype=float)
lonv = num.ndarray(dimX * dimY, dtype=float)
###########################################################################
c = 0
streamCounter = 0
for key in calcStreamMap.iterkeys():
streamID = key
c2 = 0
for o in calcStreamMap[key]:
if c2 < minSampleCount:
traces[c][c2] = o
c2 += 1
for key in TTTGridMap.iterkeys():
if streamID == key:
traveltimes[streamCounter] = TTTGridMap[key]
else:
"NEIN", streamID, key
if not streamCounter in traveltimes:
continue #hs : thread crashed before
g = traveltimes[streamCounter]
dimZ = g.dimZ
mint = g.mint
gridElem = g.GridArray
for x in range(dimX):
for y in range(dimY):
elem = gridElem[x, y]
traveltime[c][x * dimY + y] = elem.tt
latv[x * dimY + y] = elem.lat
lonv[x * dimY + y] = elem.lon
#endfor
c += 1
streamCounter += 1
#endfor
################ CALCULATE PARAMETER FOR SEMBLANCE CALCULATION ########
nsamp = winlen * new_frequence
nstep = step * new_frequence
migpoints = dimX * dimY
dimZ = 0
maxp = int(Config['ncore'])
Logfile.add('PROCESS %d NTIMES: %d' % (flag, ntimes))
if False:
print('nostat ', nostat, type(nostat))
print('nsamp ', nsamp, type(nsamp))
print('ntimes ', ntimes, type(ntimes))
print('nstep ', nstep, type(nstep))
print('dimX ', dimX, type(dimX))
print('dimY ', dimY, type(dimY))
print('mint ', Gmint, type(mint))
print('new_freq ', new_frequence, type(new_frequence))
print('minSampleCount ', minSampleCount, type(minSampleCount))
print('latv ', latv, type(latv))
print('traces', traces, type(traces))
#===================compressed sensing=================================
try:
cs = cfg.cs()
except:
cs = 0
if cs == 1:
csmaxvaluev = num.ndarray(ntimes, dtype=float)
csmaxlatv = num.ndarray(ntimes, dtype=float)
csmaxlonv = num.ndarray(ntimes, dtype=float)
folder = Folder['semb']
fobjcsmax = open(os.path.join(folder, 'csmax_%s.txt' % (switch)), 'w')
traveltimes = traveltime.reshape(1, nostat * dimX * dimY)
traveltime2 = toMatrix(traveltimes, dimX * dimY) # for relstart
traveltime = traveltime.reshape(dimX * dimY, nostat)
import matplotlib as mpl
import scipy.optimize as spopt
import scipy.fftpack as spfft
import scipy.ndimage as spimg
import cvxpy as cvx
import matplotlib.pyplot as plt
A = spfft.idct(traveltime, norm='ortho', axis=0)
n = (nostat * dimX * dimY)
vx = cvx.Variable(dimX * dimY)
res = cvx.Variable(1)
objective = cvx.Minimize(cvx.norm(res, 1))
back2 = num.zeros([dimX, dimY])
l = int(nsamp)
fobj = open(
os.path.join(folder,
'%s-%s_%03d.cs' % (switch, Origin['depth'], l)), 'w')
for i in range(ntimes):
ydata = []
try:
for tr in traces:
relstart = int((dimX * dimY - mint) * new_frequence +
0.5) + i * nstep
tr = spfft.idct(tr[relstart + i:relstart + i +
dimX * dimY],
norm='ortho',
axis=0)
ydata.append(tr)
ydata = num.asarray(ydata)
ydata = ydata.reshape(dimX * dimY, nostat)
constraints = [
res == cvx.sum_entries(0 + num.sum([
ydata[:, x] - A[:, x] * vx for x in range(nostat)
]))
]
prob = cvx.Problem(objective, constraints)
result = prob.solve(verbose=False, max_iters=200)
x = num.array(vx.value)
x = num.squeeze(x)
back1 = x.reshape(dimX, dimY)
sig = spfft.idct(x, norm='ortho', axis=0)
back2 = back2 + back1
xs = num.array(res.value)
xs = num.squeeze(xs)
max_cs = num.max(back1)
idx = num.where(back1 == back1.max())
csmaxvaluev[i] = max_cs
csmaxlatv[i] = latv[idx[0]]
csmaxlonv[i] = lonv[idx[1]]
fobj.write('%.5f %.5f %.20f\n' %
(latv[idx[0]], lonv[idx[1]], max_cs))
fobjcsmax.write('%.5f %.5f %.20f\n' %
(latv[idx[0]], lonv[idx[1]], max_cs))
fobj.close()
fobjcsmax.close()
except:
pass
#==================================semblance calculation========================================
t1 = time.time()
traces = traces.reshape(1, nostat * minSampleCount)
traveltimes = traveltime.reshape(1, nostat * dimX * dimY)
USE_C_CODE = False
#try:
if USE_C_CODE:
import Cm
import CTrig
start_time = time.time()
k = Cm.otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltimes,
traces)
print("--- %s seconds ---" % (time.time() - start_time))
else:
start_time = time.time()
ntimes = int((forerun + duration) / step)
nsamp = int(winlen)
nstep = int(step)
Gmint = cfg.Int('forerun')
k = otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltimes,
traces, calcStreamMap, timeev)
print("--- %s seconds ---" % (time.time() - start_time))
#except ValueError:
# k = Cm.otest(maxp,nostat,nsamp,ntimes,nstep,dimX,dimY,Gmint,new_frequence,
# minSampleCount,latv,lonv,traveltimes,traces)
# print "loaded tttgrid has probably wrong dimensions or stations,\
# delete ttgrid or exchange is recommended"
t2 = time.time()
Logfile.add('%s took %0.3f s' % ('CALC:', (t2 - t1)))
partSemb = k
partSemb = partSemb.reshape(ntimes, migpoints)
return partSemb, weight, array_center
def doCalc(flag, Config, WaveformDict, FilterMetaData, Gmint, Gmaxt,
TTTGridMap, Folder, Origin, ntimes):
'''
method for calculating semblance of one station array
'''
Logfile.add('PROCESS %d %s' % (flag, ' Enters Semblance Calculation'))
Logfile.add('MINT : %f MAXT: %f Traveltime' % (Gmint, Gmaxt))
cfg = ConfigObj(dict=Config)
dimX = cfg.dimX() # ('dimx')
dimY = cfg.dimY() # ('dimy')
winlen = cfg.winlen() # ('winlen')
step = cfg.step() # ('step')
new_frequence = cfg.newFrequency() # ('new_frequence')
forerun = cfg.Int('forerun')
duration = cfg.Int('duration')
gridspacing = cfg.Float('gridspacing')
nostat = len(WaveformDict)
traveltimes = {}
recordstarttime = ''
minSampleCount = 999999999
ntimes = int((forerun + duration) / step)
nsamp = int(winlen * new_frequence)
nstep = int(step * new_frequence)
#for i in WaveformDict.iterkeys():
# print i,WaveformDict[i]
############################################################################
calcStreamMap = WaveformDict
for trace in calcStreamMap.iterkeys():
recordstarttime = calcStreamMap[trace].stats.starttime
d = calcStreamMap[trace].stats.starttime
d = d.timestamp
if calcStreamMap[trace].stats.npts < minSampleCount:
minSampleCount = calcStreamMap[trace].stats.npts
############################################################################
traces = np.ndarray(shape=(len(calcStreamMap), minSampleCount),
dtype=float)
traveltime = np.ndarray(shape=(len(calcStreamMap), dimX * dimY),
dtype=float)
latv = np.ndarray(dimX * dimY, dtype=float)
lonv = np.ndarray(dimX * dimY, dtype=float)
############################################################################
#traces = np.ndarray (nostat*minSampleCount,dtype=float)
#traveltimes = np.ndarray (nostat*dimX*dimY,dtype=float)
#latv = np.ndarray (dimX*dimY,dtype=float)
#lonv = np.ndarray (dimX*dimY,dtype=float)
#print 'minSC: ',minSampleCount,' LCSM: ',len(calcStreamMap)
c = 0
streamCounter = 0
for key in calcStreamMap.iterkeys():
streamID = key
c2 = 0
#print streamID, len(calcStreamMap[key]),minSampleCount
for o in calcStreamMap[key]:
if c2 < minSampleCount:
traces[c][c2] = o
#print 'C: ',c,' C2: ',c2,' TRACES:',traces[c][c2]
c2 += 1
#endfor
for key in TTTGridMap.iterkeys():
if streamID == key:
traveltimes[streamCounter] = TTTGridMap[key]
else:
"NEIN", streamID, key
#endfor
if not streamCounter in traveltimes:
continue #hs : thread crashed before
g = traveltimes[streamCounter]
dimZ = g.dimZ
mint = g.mint
maxt = g.maxt
Latul = g.Latul
Lonul = g.Lonul
Lator = g.Lator
Lonor = g.Lonor
gridElem = g.GridArray
for x in range(dimX):
for y in range(dimY):
elem = gridElem[x, y]
traveltime[c][x * dimY + y] = elem.tt
latv[x * dimY + y] = elem.lat
lonv[x * dimY + y] = elem.lon
#endfor
c += 1
streamCounter += 1
#endfor
############################## CALCULATE PARAMETER FOR SEMBLANCE CALCULATION ##################
nsamp = winlen * new_frequence
nstep = int(step * new_frequence)
migpoints = dimX * dimY
dimZ = 0
new_frequence = cfg.newFrequency() # ['new_frequence']
maxp = int(Config['ncore'])
#maxp = 20 #hs
Logfile.add('PROCESS %d NTIMES: %d' % (flag, ntimes))
#k = Csemblance.semb(flag,nostat,nsamp,ntimes,nstep,Gmint,Gmaxt,Lonul,Latul,minSampleCount,
# dimZ,dimX,dimY,new_frequence,ntimesstart,ntimesend,winlen,step,gridspacing,
# latv,lonv,traveltime,traces,backveclen)
#k = sembPar.semb (flag,nostat,nsamp,ntimes,nstep,Gmint,Gmaxt,Lonul,Latul,minSampleCount,dimZ,
# dimX,dimY,new_frequence,ntimesstart,ntimesend,winlen,step,gridspacing,latv,
# lonv,traveltime,traces,backveclen)
if False:
print('nostat ', nostat, type(nostat))
print('nsamp ', nsamp, type(nsamp))
print('ntimes ', ntimes, type(ntimes))
print('nstep ', nstep, type(nstep))
print('dimX ', dimX, type(dimX))
print('dimY ', dimY, type(dimY))
print('mint ', Gmint, type(mint))
print('new_freq ', new_frequence, type(new_frequence))
print('minSampleCount ', minSampleCount, type(minSampleCount))
print('latv ', latv, type(latv))
print('traces', traces, type(traces))
print('traveltime', traveltime, type(traveltime))
traveltime = traveltime.reshape(1, nostat * dimX * dimY)
traces = traces.reshape(1, nostat * minSampleCount)
#print 'traveltime2',traveltime,type(traveltime)
t1 = time.time()
if USE_C_CODE:
k = Cm.otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltime,
traces)
else:
k = otest(maxp, nostat, nsamp, ntimes, nstep, dimX, dimY, Gmint,
new_frequence, minSampleCount, latv, lonv, traveltime,
traces) #hs
t2 = time.time()
Logfile.add('%s took %0.3f s' % ('CALC:', (t2 - t1)))
#print 'K',k,len(k),' MUST ',ntimes*dimX*dimY,' RES ',k[1]
partSemb = k
#partSemb = partSemb.reshape (1,migpoints)
partSemb = partSemb.reshape(ntimes, migpoints)
#print 'PARTSEMB FLAG: ',partSemb,type(partSemb),partSemb.ndim
return partSemb
def calcTTTAdvTauP(Config,
station,
Origin,
flag,
Xcorrshift=None,
Refshift=None):
cfg = ConfigObj(dict=Config)
dimX = cfg.Int('dimx')
dimY = cfg.Int('dimy')
gridspacing = cfg.Float('gridspacing')
o_lat = float(Origin['lat'])
o_lon = float(Origin['lon'])
o_depth = float(Origin['depth'])
oLator = o_lat + dimX / 2
oLonor = o_lon + dimY / 2
oLatul = 0
oLonul = 0
TTTGridMap = {}
LMINMAX = []
GridArray = {}
locStation = Location(station.lat, station.lon)
sdelta = loc2degrees(Location(o_lat, o_lon), locStation)
Logfile.add('TTT PROCESS %d STATION: %s --> DELTA: %f' %
(flag, station.getName(), sdelta))
inputpath = str(flag) + '-' + station.getName() + ".input"
outputpath = str(flag) + '-' + station.getName() + ".output"
errorpath = str(flag) + '-' + station.getName() + '.error'
fobjinput = open(inputpath, 'w')
fobjinput.write('s\n')
fobjinput.write(('%s %s\n') % (station.lat, station.lon))
fobjinput.write('h\n')
fobjinput.write(('%s\n') % (o_depth))
for i in xrange(dimX):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
for j in xrange(dimY):
oLonul = o_lon - ((dimY - 1) / 2) * gridspacing + j * gridspacing
fobjinput.write('e\n')
fobjinput.write(('%s %s\n') % (oLatul, oLonul))
#endfor
fobjinput.close()
cmd = ('taup_time -ph P -mod ak135 -time -o %s < %s > %s') % (
outputpath, inputpath, errorpath)
#os.system(cmd)
p = subprocess.Popen(cmd,
shell=True,
stdout=subprocess.PIPE,
stderr=subprocess.STDOUT)
p.wait()
L = []
output = open(outputpath, 'r')
'OUTPUT: ', outputpath
for k in output:
k = k.split()
if len(k) == 1:
tt = k[0].replace('\n', '')
tt = float(tt) - float(Xcorrshift[station.getName()].shift)
L.append(tt)
#endfor
output.close()
z = 0
for i in xrange(dimX):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
for j in xrange(dimY):
oLonul = o_lon - ((dimY - 1) / 2) * gridspacing + j * gridspacing
if o == 0 and j == 0:
Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
time = L[i * dimX + j]
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, time, de)
LMINMAX.append(time)
#endfor
mint = float(min(LMINMAX))
maxt = float(max(LMINMAX))
k = MinTMaxT(mint, maxt)
TTTGridMap[station.getName()] = TTTGrid(o_depth, mint, maxt, Latul, Lonul,
oLator, oLonor, GridArray)
tttname = str(flag) + '-ttt.pkl'
Basic.dumpToFile(tttname, TTTGridMap)
Basic.dumpToFile('minmax-' + str(flag) + '.pkl', k)
try:
os.remove(inputpath)
os.remove(outputpath)
os.remove(errorpath)
except:
Logfile.exception('cannot delete files')
def processLoop():
C = config.Config(evpath)
Origin = C.parseConfig('origin')
flag_rpe = False
try:
Syn_in = C.parseConfig('syn')
syn_in = SynthCfg(Syn_in)
except TypeError:
pass
Config = C.parseConfig('config')
cfg = ConfigObj(dict=Config)
phases = cfg.Str('ttphases')
phases = phases.split(',')
if cfg.pyrocko_download() is True:
Meta = C.readpyrockostations()
elif cfg.colesseo_input() is True:
scenario = guts.load(filename=cfg.colosseo_scenario_yml())
scenario_path = cfg.colosseo_scenario_yml()[:-12]
Meta = C.readcolosseostations(scenario_path)
else:
Meta = C.readMetaInfoFile()
Folder = C.createFolder()
C.writeConfig(Config, Origin, Folder)
filter = FilterCfg(Config)
if cfg.UInt('forerun') > 0:
ntimes = int(
(cfg.UInt('forerun') + cfg.UInt('duration')) / cfg.UInt('step'))
else:
ntimes = int((cfg.UInt('duration')) / cfg.UInt('step'))
origin = OriginCfg(Origin)
if cfg.colesseo_input() is True:
from pyrocko import util
events = scenario.get_events()
ev = events[0]
origin.strike = str(ev.moment_tensor.strike1)
origin.rake = str(ev.moment_tensor.rake1)
origin.dip = str(ev.moment_tensor.dip1)
strike = ev.moment_tensor.strike1
origin.lat = str(ev.lat)
origin.lon = str(ev.lon)
origin.depth = str(ev.depth / 1000.)
depth = ev.depth
origin.time = util.time_to_str(ev.time)
time_ev = util.time_to_str(ev.time)
lat = ev.lat
lon = ev.lon
rake = ev.moment_tensor.rake1
dip = ev.moment_tensor.dip1
Origin['strike'] = str(ev.moment_tensor.strike1)
Origin['rake'] = str(ev.moment_tensor.rake1)
Origin['dip'] = str(ev.moment_tensor.dip1)
Origin['lat'] = str(ev.lat)
Origin['lon'] = str(ev.lon)
Origin['time'] = util.time_to_str(ev.time)
Origin['depth'] = str(ev.depth / 1000.)
ev = Event(lat, lon, depth, time_ev, strike=strike, dip=dip, rake=rake)
else:
default = 0
strike = origin.strike(default)
dip = origin.dip(default)
rake = origin.rake(default)
ev = Event(origin.lat(),
origin.lon(),
origin.depth(),
origin.time(),
strike=strike,
dip=dip,
rake=rake)
if cfg.Bool('correct_shifts_empirical') is True:
Origin_emp = C.parseConfig('origin_emp')
origin_emp = OriginCfg(Origin_emp)
ev_emp = Event(origin_emp.lat(),
origin_emp.lon(),
origin_emp.depth(),
origin_emp.time(),
strike=strike,
dip=dip,
rake=rake)
filtername = filter.filterName()
Logfile.add('filtername = ' + filtername)
XDict = OrderedDict()
RefDict = OrderedDict()
SL = OrderedDict()
refshifts_global = []
newFreq = str(filter.newFrequency())
xcorrnetworks = cfg.String('networks').split(',')
if cfg.Int('xcorr') is 1:
fobjreferenceshiftname = newFreq + '_' + filtername + '.refpkl'
rp = os.path.join(Folder['semb'], fobjreferenceshiftname)
fobjreferenceshiftnameemp = newFreq + '_' + filtername + 'emp' + '.refpkl'
rpe = os.path.join(Folder['semb'], fobjreferenceshiftnameemp)
fobjpickleshiftname = newFreq + '_' + filtername + '.xcorrpkl'
ps = os.path.join(Folder['semb'], fobjpickleshiftname)
if (os.path.isfile(rp) and os.path.getsize(rp) != 0
and os.path.isfile(ps) and os.path.getsize(ps) != 0):
Logfile.add('xcorr/reference shift file exits : ' + rp)
Logfile.add('loaded reference shift')
if sys.version_info.major >= 3:
f = open(rp, 'rb')
else:
f = open(rp)
RefDict = pickle.load(f)
if sys.version_info.major >= 3:
x = open(ps, 'rb')
else:
x = open(ps)
XDict = pickle.load(x)
for i in xcorrnetworks:
SL[i] = len(Config[i].split('|'))
else:
SL = {}
for i in xcorrnetworks:
W = {}
network = cfg.String(i).split('|')
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
arrayfolder = os.path.join(Folder['semb'], i)
if os.access(arrayfolder, os.F_OK) is False:
os.makedirs(arrayfolder)
if cfg.pyrocko_download() is True:
# TODO check seperate xcoor nescessity
A = Xcorr(ev, FilterMeta, evpath, Config, Syn_in,
arrayfolder)
print("run Xcorr")
phase = phases[0]
W, triggerobject = A.runXcorr(phase)
XDict[i] = W
RefDict[i] = triggerobject.tdiff
SL[i] = len(network)
for j in range(0, len(FilterMeta)):
refshifts_global.append(triggerobject.tdiff)
if sys.version_info.major >= 3:
fobjrefshift = open(rp, 'wb')
else:
fobjrefshift = open(rp, 'w')
pickle.dump(RefDict, fobjrefshift)
fobjrefshift.close()
if sys.version_info.major >= 3:
output = open(ps, 'wb')
else:
output = open(ps, 'w')
pickle.dump(XDict, output)
output.close()
else:
fobjreferenceshiftname = newFreq + '_' + filtername + '.refpkl'
rp = os.path.join(Folder['semb'], fobjreferenceshiftname)
fobjreferenceshiftnameemp = newFreq + '_' + filtername + 'emp' + '.refpkl'
rpe = os.path.join(Folder['semb'], fobjreferenceshiftnameemp)
fobjpickleshiftname = newFreq + '_' + filtername + '.xcorrpkl'
ps = os.path.join(Folder['semb'], fobjpickleshiftname)
refshift = 0
if (os.path.isfile(rp) and os.path.getsize(rp) != 0
and os.path.isfile(ps) and os.path.getsize(ps) != 0):
Logfile.add('Temporay Memory file exits : ' + rp)
if sys.version_info.major >= 3:
f = open(rp, 'rb')
else:
f = open(rp)
RefDict = pickle.load(f)
if sys.version_info.major >= 3:
x = open(ps, 'rb')
else:
x = open(ps)
XDict = pickle.load(x)
for i in xcorrnetworks:
SL[i] = len(Config[j].split('|'))
network = cfg.String(i).split('|')
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
RefDict[i] = refshift
for j in range(0, len(FilterMeta)):
refshifts_global.append(refshift)
else:
SL = {}
for i in xcorrnetworks:
W = {}
refshift = 0
network = cfg.String(i).split('|')
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
arrayfolder = os.path.join(Folder['semb'], i)
if os.access(arrayfolder, os.F_OK) is False:
os.makedirs(arrayfolder)
if cfg.pyrocko_download() is True:
# TODO check seperate xcoor nescessity
A = Xcorr(ev, FilterMeta, evpath, Config, Syn_in,
arrayfolder)
else:
A = Xcorr(ev, FilterMeta, evpath, Config, Syn_in,
arrayfolder)
print("run Xcorr")
phase = phases[0]
W, triggerobject = A.runXcorr_dummy(phase)
XDict[j] = W
RefDict[j] = refshift
SL[j] = len(network)
for j in range(0, len(FilterMeta)):
refshifts_global.append(refshift)
if sys.version_info.major >= 3:
fobjrefshift = open(rp, 'wb')
else:
fobjrefshift = open(rp, 'w')
pickle.dump(RefDict, fobjrefshift)
fobjrefshift.close()
if sys.version_info.major >= 3:
output = open(ps, 'wb')
else:
output = open(ps, 'w')
pickle.dump(XDict, output)
output.close()
if sys.version_info.major >= 3:
for j in sorted(XDict.keys()):
Logfile.red('Array %s has %3d of %3d Stations left' %
(j, len(XDict[j]), SL[j]))
else:
for j in sorted(XDict.keys()):
Logfile.red('Array %s has %3d of %3d Stations left' %
(j, len(XDict[j]), SL[j]))
while True:
if sys.version_info.major >= 3:
nnl = input("please enter your choice: ")
else:
nnl = raw_input("please enter your choice: ")
if len(nnl) == 0:
if not Basic.question('Process all networks ?'):
continue
Logfile.red('This networks will be used for processing: %s' %
(Config['networks']))
break
elif str(nnl) == 'quit':
sys.exit()
elif str(nnl) == 'rerun':
event = os.path.join(*evpath.split('/')[-1:])
try:
os.remove(rp)
os.remove(ps)
except Exception:
pass
mainfolder = os.path.join(os.path.sep, *evpath.split('/')[:-2])
os.chdir(mainfolder)
cmd = ('%s arraytool.py process %s') % (sys.executable, event)
Logfile.add('cmd = ' + cmd)
os.system(cmd)
sys.exit()
else:
names = nnl.split(',')
isOk = True
for array in names:
arrayfolder = os.path.join(Folder['semb'], array)
if not os.path.isdir(arrayfolder):
Logfile.error('Illegal network name ' + str(array))
isOk = False
break
if not isOk:
continue
Logfile.add('This networks will be used for processing: %s' %
(nnl))
Config['networks'] = nnl
break
for j in range(3, 0, -1):
time.sleep(1)
Logfile.red('Start processing in %d seconds ' % (j))
wd = Origin['depth']
start, stop, step = cfg.String('depths').split(',')
start = int(start)
stop = int(stop) + 1
step_depth = int(step)
filters = cfg.String('filters')
filters = int(filters)
Logfile.add('working on ' + Config['networks'])
if cfg.Bool('correct_shifts_empirical') is True:
emp_loop = True
else:
emp_loop = False
# ==================================loop over phases======================
for phase in phases:
if phase is 'P':
desired = 'Z'
if phase is 'S':
desired = 'T'
# ==================================loop over filter setups=====
for filterindex in xrange(0, filters):
# ==================================loop over depth=======
for depthindex in xrange(start, stop, step_depth):
workdepth = float(wd) + depthindex
Origin['depth'] = workdepth
ev = Event(Origin['lat'],
Origin['lon'],
Origin['depth'],
Origin['time'],
strike=strike,
dip=dip,
rake=rake)
Logfile.add('WORKDEPTH: ' + str(Origin['depth']))
networks = Config['networks'].split(',')
ASL = []
weights = []
array_centers = []
counter = 1
stations_per_array = []
Wdfs = []
Wdfs_emp = []
FilterMetas = []
TTTgrids = OrderedDict()
mints = []
maxts = []
refshifts = []
for i in networks:
arrayname = i
arrayfolder = os.path.join(Folder['semb'], arrayname)
network = Config[i].split('|')
Logfile.add('network: ' + str(network))
FilterMeta = ttt.filterStations(Meta, Config, Origin,
network)
W = XDict[i]
refshift = RefDict[i]
for j in range(0, len(FilterMeta)):
if cfg.correct_shifts() is False:
refshift = refshift * 0.
refshifts.append(refshift)
FilterMeta = cmpFilterMetavsXCORR(W, FilterMeta)
Logfile.add('BOUNDING BOX DIMX: %s DIMY: %s GRIDSPACING:\
%s \n' % (Config['dimx'], Config['dimy'],
Config['gridspacing']))
Logfile.red('Calculating Traveltime Grid')
t1 = time.time()
isParallel = False
TTTGridMap = []
mint = []
maxt = []
ttt_model = cfg.Str('traveltime_model')
try:
if cfg.Bool('correct_shifts_empirical') is True:
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s_emp.pkl' %
(phase, ttt_model, ev_emp.time, arrayname,
workdepth), 'rb')
print(
"loading travel time grid%s_%s_%s_%s_%s_emp.pkl"
% (phase, ttt_model, ev_emp.time, arrayname,
workdepth))
TTTGridMap_emp, mint_emp, maxt_emp = pickle.load(f)
f.close()
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s.pkl' %
(phase, ttt_model, ev.time, arrayname, workdepth),
'rb')
print(
"loading travel time grid%s_%s_%s_%s_%s.pkl" %
(phase, ttt_model, ev.time, arrayname, workdepth))
TTTGridMap, mint, maxt = pickle.load(f)
f.close()
print("loading of travel time grid sucessful")
except Exception:
print("loading of travel time grid unsucessful,\n \
will now calculate the grid:")
if isParallel:
maxp = 6
po = multiprocessing.Pool(maxp)
for i in xrange(len(FilterMeta)):
po.apply_async(ttt.calcTTTAdv,
(Config, FilterMeta[i], Origin,
i, arrayname, W, refshift))
po.close()
po.join()
else:
for i in xrange(len(FilterMeta)):
t1 = time.time()
ttt.calcTTTAdv(Config, FilterMeta[i], Origin,
i, arrayname, W, refshift,
phase)
Logfile.add('ttt.calcTTTAdv : ' +
str(time.time() - t1) + ' sec.')
assert len(FilterMeta) > 0
TTTGridMap = deserializer.deserializeTTT(
len(FilterMeta))
mint, maxt = deserializer.deserializeMinTMaxT(
len(FilterMeta))
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s.pkl' %
(phase, ttt_model, ev.time, arrayname, workdepth),
'wb')
print("dumping the traveltime grid for this array")
pickle.dump([TTTGridMap, mint, maxt], f)
f.close()
if cfg.Bool('correct_shifts_empirical') is True:
ttt.calcTTTAdv(Config, FilterMeta[i], Origin_emp,
i, arrayname, W, refshift, phase)
assert len(FilterMeta) > 0
TTTGridMap_emp = deserializer.deserializeTTT(
len(FilterMeta))
mint_emp, maxt_emp = deserializer.deserializeMinTMaxT(
len(FilterMeta))
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s_emp.pkl' %
(phase, ttt_model, ev_emp.time, arrayname,
workdepth), 'wb')
print("dumping the traveltime grid for this array")
pickle.dump([TTTGridMap_emp, mint_emp, maxt_emp],
f)
f.close()
t2 = time.time()
Logfile.red('%s took %0.3f s' % ('TTT', (t2 - t1)))
switch = filterindex
tw = times.calculateTimeWindows(mint, maxt, Config, ev,
switch)
if cfg.Bool('correct_shifts_empirical') is True:
tw_emp = times.calculateTimeWindows(
mint_emp, maxt_emp, Config, ev_emp, switch)
if cfg.pyrocko_download() is True:
if cfg.quantity() == 'displacement':
Wd_emp = waveform.readWaveformsPyrocko_restituted(
FilterMeta, tw, evpath, ev_emp, desired)
elif cfg.Bool('synthetic_test') is True:
Wd_emp = waveform.readWaveformsPyrockodummy(
FilterMeta, tw_emp, evpath_emp, ev_emp)
else:
Wd_emp = waveform.readWaveformsPyrocko(
FilterMeta, tw_emp, evpath_emp, ev_emp,
desired)
elif cfg.colesseo_input() is True:
Wd_emp = waveform.readWaveforms_colesseo(
FilterMeta, tw_emp, evpath_emp, ev_emp, C)
else:
Wd_emp = waveform.readWaveforms(
FilterMeta, tw_emp, evpath_emp, ev_emp)
if cfg.Bool('synthetic_test') is True\
or cfg.Bool('dynamic_filter') is True:
Wdf_emp = waveform.processdummyWaveforms(
Wd_emp, Config, Folder, arrayname, FilterMeta,
ev_emp, switch, W)
Wdfs_emp.extend(Wdf_emp)
else:
Wdf_emp = waveform.processWaveforms(
Wd_emp, Config, Folder, arrayname, FilterMeta,
ev_emp, switch, W)
Wdfs_emp.extend(Wdf_emp)
if cfg.pyrocko_download() is True:
if cfg.quantity() == 'displacement':
Wd = waveform.readWaveformsPyrocko_restituted(
FilterMeta, tw, evpath, ev, desired)
elif cfg.Bool('synthetic_test') is True:
Wd = waveform.readWaveformsPyrockodummy(
FilterMeta, tw, evpath, ev)
else:
Wd = waveform.readWaveformsPyrocko(
FilterMeta, tw, evpath, ev, desired)
elif cfg.colesseo_input() is True:
Wd = waveform.readWaveforms_colesseo(
FilterMeta, tw, evpath, ev, C)
else:
Wd = waveform.readWaveforms(FilterMeta, tw, evpath, ev)
if cfg.Bool('synthetic_test') is True\
or cfg.Bool('dynamic_filter') is True:
Wdf = waveform.processdummyWaveforms(
Wd, Config, Folder, arrayname, FilterMeta, ev,
switch, W)
Wdfs.extend(Wdf)
else:
Wdf = waveform.processWaveforms(
Wd, Config, Folder, arrayname, FilterMeta, ev,
switch, W)
Wdfs.extend(Wdf)
C.writeStationFile(FilterMeta, Folder, counter)
Logfile.red('%d Streams added for Processing' % (len(Wd)))
t1 = time.time()
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s.pkl' %
(phase, ttt_model, ev.time, arrayname, workdepth),
'rb')
TTTGridMap, mint, maxt = pickle.load(f)
f.close()
if switch == 0:
step = cfg.step()
if switch == 1:
step = cfg.step_f2()
if cfg.UInt('forerun') > 0:
ntimes = int(
(cfg.UInt('forerun') + cfg.UInt('duration')) /
step)
else:
ntimes = int((cfg.UInt('duration')) / step)
if cfg.Bool('combine_all') is False:
if cfg.optimize() is True:
optim.solve(counter, Config, Wdf, FilterMeta, mint,
maxt, TTTGridMap, Folder, Origin,
ntimes, switch, ev, arrayfolder,
syn_in, refshifts, phase,
rpe + str(arrayname), flag_rpe)
else:
if cfg.Bool('correct_shifts_empirical') is True:
if cfg.Bool('correct_shifts_empirical_run'
) is True:
f = open(
'../tttgrid/tttgrid%s_%s_%s_%s_%s_emp.pkl'
% (phase, ttt_model, ev_emp.time,
arrayname, workdepth), 'rb')
TTTGridMap_emp, mint_emp, maxt_emp = pickle.load(
f)
f.close()
flag_rpe = True
arraySemb, weight, array_center = sembCalc.doCalc(
counter, Config, Wdf_emp, FilterMeta,
mint, maxt, TTTGridMap_emp, Folder,
Origin, ntimes, switch, ev_emp,
arrayfolder, syn_in, refshifts, phase,
rpe + str(arrayname), flag_rpe)
if sys.version_info.major >= 3:
f = open(rpe + str(arrayname), 'rb')
else:
f = open(rpe + str(arrayname))
RefDict_empirical = pickle.load(f)
refshifts = RefDict_empirical
for j in range(0, len(FilterMeta)):
if cfg.correct_shifts() is False:
refshifts[j] = refshifts[j] * 0.
flag_rpe = False
arraySemb, weight, array_center = sembCalc.doCalc(
counter, Config, Wdf, FilterMeta, mint, maxt,
TTTGridMap, Folder, Origin, ntimes, switch, ev,
arrayfolder, syn_in, refshifts, phase,
rpe + str(arrayname), flag_rpe)
weights.append(weight)
array_centers.append(array_center)
ASL.append(arraySemb)
sembCalc.writeSembMatricesSingleArray(
arraySemb, Config, Origin, arrayfolder, ntimes,
switch, phase)
fileName = os.path.join(arrayfolder, 'stations.txt')
Logfile.add('Write to file ' + fileName)
fobjarraynetwork = open(fileName, 'w')
for i in FilterMeta:
fobjarraynetwork.write(
('%s %s %s\n') % (i.getName(), i.lat, i.lon))
fobjarraynetwork.close()
t2 = time.time()
Logfile.add('CALC took %0.3f sec' % (t2 - t1))
counter += 1
stations_per_array.append(len(FilterMeta))
TTTgrids.update(TTTGridMap)
mints.append(mint)
maxts.append(maxt)
FilterMetas[len(FilterMetas):] = FilterMeta
TTTGridMap = []
if cfg.Bool('combine_all') is True:
if cfg.pyrocko_download() is True:
if cfg.Bool('synthetic_test') is True:
Wd = waveform.readWaveformsPyrockodummy(
FilterMetas, tw, evpath, ev)
else:
if cfg.quantity() == 'displacement':
Wd = waveform.readWaveformsPyrocko_restituted(
FilterMetas, tw, evpath, ev, desired)
else:
Wd = waveform.readWaveformsPyrocko(
FilterMetas, tw, evpath, ev, desired)
elif cfg.colesseo_input() is True:
Wd = waveform.readWaveforms_colesseo(
FilterMetas, tw, evpath, ev, C)
else:
Wd = waveform.readWaveforms(FilterMetas, tw, evpath,
ev)
if cfg.Bool('synthetic_test') is True:
Wdf = waveform.processdummyWaveforms(
Wd, Config, Folder, arrayname, FilterMetas, ev,
switch, W)
else:
Wdf = waveform.processWaveforms(
Wd, Config, Folder, arrayname, FilterMetas, ev,
switch, W)
mint = num.min(mints)
maxt = num.max(maxts)
flag_rpe = False
if cfg.Bool('bootstrap_array_weights') is False:
arraySemb, weight, array_center = sembCalc.doCalc(
counter, Config, Wdf, FilterMetas, mint, maxt,
TTTgrids, Folder, Origin, ntimes, switch, ev,
arrayfolder, syn_in, refshifts_global, phase,
rpe + str(arrayname), flag_rpe)
ASL.append(arraySemb)
weights.append(weight)
array_centers.append(array_center)
sembCalc.writeSembMatricesSingleArray(
arraySemb, Config, Origin, arrayfolder, ntimes,
switch, phase)
else:
nboot = cfg.Int('n_bootstrap')
tmp_general = 1
for ibootstrap in range(nboot):
f = rstate.uniform(0., 1., size=counter + 1)
f = num.sort(f)
g = f[1:] - f[:-1]
k = 0
ws = []
for wss in range(0, counter - 1):
for stats in range(0, stations_per_array[k]):
ws.append(g[k])
k = +1
ws = num.asarray(ws)
arraySemb, weight, array_center = sembCalc.doCalc(
counter,
Config,
Wdf,
FilterMetas,
mint,
maxt,
TTTgrids,
Folder,
Origin,
ntimes,
switch,
ev,
arrayfolder,
syn_in,
refshifts_global,
phase,
rpe + str(arrayname),
flag_rpe,
bs_weights=ws)
ASL.append(arraySemb)
weights.append(weight)
array_centers.append(array_center)
sembCalc.writeSembMatricesSingleArray(
arraySemb,
Config,
Origin,
arrayfolder,
ntimes,
switch,
phase,
bootstrap=ibootstrap)
if ASL:
Logfile.red('collect semblance matrices from\
all arrays')
sembmax, tmp = sembCalc.collectSemb(
ASL,
Config,
Origin,
Folder,
ntimes,
len(networks),
switch,
array_centers,
phase,
cboot=ibootstrap)
tmp_general *= tmp
ASL = []
sembmax, tmp = sembCalc.collectSemb(
ASL,
Config,
Origin,
Folder,
ntimes,
len(networks),
switch,
array_centers,
phase,
cboot=None,
temp_comb=tmp_general)
if cfg.optimize_all() is True:
import optim_csemb
sembmax, tmp = sembCalc.collectSemb(
ASL, Config, Origin, Folder, ntimes, len(networks),
switch)
optim_csemb.solve(counter, Config, Wdf, FilterMeta, mint,
maxt, TTTGridMap, Folder, Origin, ntimes,
switch, ev, arrayfolder, syn_in, ASL,
sembmax, evpath, XDict, RefDict,
workdepth, filterindex, Wdfs)
if ASL and cfg.Bool('bootstrap_array_weights') is False:
Logfile.red('collect semblance matrices from all arrays')
sembmax, tmp = sembCalc.collectSemb(
ASL, Config, Origin, Folder, ntimes, len(networks),
switch, array_centers, phase)
if cfg.Bool('weight_by_noise') is True:
sembCalc.collectSembweighted(ASL, Config, Origin,
Folder, ntimes,
len(networks), switch,
weights)
else:
Logfile.red('Nothing to do -> Finish')
print("last work depth:")
print(workdepth)
def calcTTTAdv(Config,
station,
Origin,
flag,
arrayname,
Xcorrshift=None,
Refshift=None):
phasename = ('%sphase') % (os.path.basename(arrayname))
cfg = ConfigObj(dict=Config)
dimX = cfg.Int('dimx')
dimY = cfg.Int('dimy')
gridspacing = cfg.Float('gridspacing')
o_lat = float(Origin['lat'])
o_lon = float(Origin['lon'])
o_depth = float(Origin['depth'])
oLator = o_lat + dimX / 2
oLonor = o_lon + dimY / 2
oLatul = 0
oLonul = 0
#mint= 100000 #maxt=-100000
TTTGridMap = {}
LMINMAX = []
GridArray = {}
locStation = Location(station.lat, station.lon)
sdelta = loc2degrees(Location(o_lat, o_lon), locStation)
tt = obs_TravelTimes(sdelta, o_depth)
for r in tt:
if r['phase_name'] is Config[phasename] or r['phase_name'] == (
'%sdiff') % (Config[phasename]):
station.takeoff = r['take-off angle']
ph = r['phase_name']
#endfor
#15.12.2015 : rauskommentiert
#Logfile.add ('STATIONINFO ' + str(station) + ' ' + str(station.takeoff) + ' ' + str(ph),
# 'PROCESS %d STATION: %s --> DELTA: %f' % (flag,station,sdelta), ' ')
z = 0
for i in xrange(dimX):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
for j in xrange(dimY):
ttime = 0
oLonul = o_lon - ((dimY - 1) / 2) * gridspacing + j * gridspacing
if o == 0 and j == 0: Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
tt = obs_TravelTimes(de, o_depth)
for k in tt:
if k['phase_name'] == Config[phasename] or k['phase_name'] == (
'%sdiff') % (Config[phasename]):
ttime = k['time']
if int(Config['xcorr']) == 1:
ttime = ttime - float(
Xcorrshift[station.getName()].shift) - Refshift
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth,
ttime, de)
LMINMAX.append(ttime)
#endfor
if ttime == 0:
print '\033[31mAvailable phases for station %s in range %f deegree\033[0m' % (
station, de)
print '\033[31m' + '|'.join(
[str(item['phase_name']) for item in tt]) + '\033[0m'
print '\033[31myou tried phase %s\033[0m' % (Config[phasename])
raise Exception("\033[31mILLEGAL: phase definition\033[0m")
#endif
#endfor
#endfor
mint = min(LMINMAX)
maxt = max(LMINMAX) # maxt = time
TTTGridMap[station.getName()] = TTTGrid(o_depth, mint, maxt, Latul, Lonul,
oLator, oLonor, GridArray)
k = MinTMaxT(mint, maxt)
Basic.dumpToFile(str(flag) + '-ttt.pkl', TTTGridMap)
Basic.dumpToFile('minmax-' + str(flag) + '.pkl', k)
Basic.dumpToFile('station-' + str(flag) + '.pkl', station)
def calcTTTAdv(Config, station, Origin, flag, arrayname, Xcorrshift, Refshift,
phase):
cfg = ConfigObj(dict=Config)
if cfg.Bool('correct_shifts_empirical') is True:
dimX = cfg.Int('dimx_emp')
dimY = cfg.Int('dimy_emp')
else:
dimX = cfg.Int('dimx')
dimY = cfg.Int('dimy')
gridspacing = cfg.Float('gridspacing')
traveltime_model = cfg.Str('traveltime_model')
o_lat = float(Origin['lat'])
o_lon = float(Origin['lon'])
o_depth = float(Origin['depth'])
oLator = o_lat + dimX / 2
oLonor = o_lon + dimY / 2
oLatul = 0
oLonul = 0
o_dip = 80.
plane = False
TTTGridMap = {}
LMINMAX = []
GridArray = {}
locStation = Location(station.lat, station.lon)
sdelta = loc2degrees(Location(o_lat, o_lon), locStation)
Phase = cake.PhaseDef(phase)
model = cake.load_model('../data/' + traveltime_model)
z = 0
if plane is True:
depth = np.linspace(0., 40., num=dimY)
for i in xrange(70):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
start_time = time.clock()
for j in xrange(40):
oLonul = o_lon - (
(dimY - 1) /
2) * gridspacing + j * gridspacing / np.cos(o_dip)
if o == 0 and j == 0:
Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=depth[j] * km,
zstop=0.)
try:
ttime = arrivals[0].t
except Exception:
try:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=depth[j] * km - 2.5,
zstop=depth[j] * km + 2.5,
refine=True)
ttime = arrivals[0].t
except Exception:
tt = obs_TravelTimes(de, o_depth)
for k in tt:
if k['phase_name'] == 'P' or k['phase_name'] == (
'%sdiff') % (Config[phasename]):
ttime = k['time']
print("Something wrong with phase arrival, too large\
distances choosen?")
GridArray[(i, j)] = GridElem(oLatul, oLonul, depth[j], ttime,
de)
LMINMAX.append(ttime)
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
if ttime == 0:
raise Exception("\033[31mILLEGAL: phase definition\033[0m")
else:
for i in xrange(dimX):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
for j in xrange(dimY):
oLonul = o_lon - (
(dimY - 1) / 2) * gridspacing + j * gridspacing
if o == 0 and j == 0:
Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km)
try:
ttime = arrivals[0].t
except:
try:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km,
zstop=o_depth * km,
refine=True)
ttime = arrivals[0].t
except:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km - 2.5,
zstop=o_depth * km + 2.5,
refine=True)
ttime = arrivals[0].t
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
if ttime == 0:
raise Exception("\033[31mILLEGAL: phase definition\033[0m")
mint = min(LMINMAX)
maxt = max(LMINMAX)
TTTGridMap[station.getName()] = TTTGrid(o_depth, mint, maxt, Latul, Lonul,
oLator, oLonor, GridArray)
k = MinTMaxT(mint, maxt)
Basic.dumpToFile(str(flag) + '-ttt.pkl', TTTGridMap)
Basic.dumpToFile('minmax-' + str(flag) + '.pkl', k)
Basic.dumpToFile('station-' + str(flag) + '.pkl', station)
def doCalc_syn (flag,Config,WaveformDict,FilterMetaData,Gmint,Gmaxt,TTTGridMap,
Folder,Origin, ntimes, switch, ev,arrayfolder, syn_in, parameter):
'''
method for calculating semblance of one station array
'''
Logfile.add ('PROCESS %d %s' % (flag,' Enters Semblance Calculation') )
Logfile.add ('MINT : %f MAXT: %f Traveltime' % (Gmint,Gmaxt))
cfg = ConfigObj (dict=Config)
dimX = cfg.dimX() # ('dimx')
dimY = cfg.dimY() # ('dimy')
winlen = cfg.winlen () # ('winlen')
step = cfg.step() # ('step')
new_frequence = cfg.newFrequency() #('new_frequence')
forerun= cfg.Int('forerun')
duration= cfg.Int('duration')
gridspacing = cfg.Float('gridspacing')
nostat = len (WaveformDict)
traveltimes = {}
recordstarttime = ''
minSampleCount = 999999999
ntimes = int ((forerun + duration)/step)
nsamp = int (winlen * new_frequence)
nstep = int (step * new_frequence)
from pyrocko import obspy_compat
from pyrocko import orthodrome, model
obspy_compat.plant()
############################################################################
calcStreamMap = WaveformDict
stations = []
py_trs = []
for trace in calcStreamMap.iterkeys():
py_tr = obspy_compat.to_pyrocko_trace(calcStreamMap[trace])
py_trs.append(py_tr)
for il in FilterMetaData:
if str(il) == str(trace):
szo = model.Station(lat=il.lat, lon=il.lon,
station=il.sta, network=il.net,
channels=py_tr.channel,
elevation=il.ele, location=il.loc)
stations.append(szo) #right number of stations?
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
targets = []
for st in stations:
target = Target(
lat=st.lat,
lon=st.lon,
store_id=store_id,
codes=(st.network, st.station, st.location, 'BHZ'),
tmin=-1900,
tmax=3900,
interpolation='multilinear',
quantity=cfg.quantity())
targets.append(target)
if syn_in.nsources() == 1:
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
source = RectangularSource(
lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
depth=syn_in.depth_syn_0()*1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
width=syn_in.width_0()*1000.,
length=syn_in.length_0()*1000.,
nucleation_x=syn_in.nucleation_x_0(),
slip=syn_in.slip_0(),
nucleation_y=syn_in.nucleation_y_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0()))
if syn_in.source() == 'DCSource':
source = DCSource(
lat=float(syn_in.lat_0()),
lon=float(syn_in.lon_0()),
depth=syn_in.depth_syn_0()*1000.,
strike=syn_in.strike_0(),
dip=syn_in.dip_0(),
rake=syn_in.rake_0(),
stf=stf,
time=util.str_to_time(syn_in.time_0()),
magnitude=syn_in.magnitude_0())
else:
sources = []
for i in range(syn_in.nsources()):
if syn_in.use_specific_stf() is True:
stf = syn_in.stf()
exec(stf)
else:
stf = STF()
if syn_in.source() == 'RectangularSource':
sources.append(RectangularSource(
lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
depth=syn_in.depth_syn_1(i)*1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
width=syn_in.width_1(i)*1000.,
length=syn_in.length_1(i)*1000.,
nucleation_x=syn_in.nucleation_x_1(i),
slip=syn_in.slip_1(i),
nucleation_y=syn_in.nucleation_y_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i))))
if syn_in.source() == 'DCSource':
sources.append(DCSource(
lat=float(syn_in.lat_1(i)),
lon=float(syn_in.lon_1(i)),
depth=syn_in.depth_1(i)*1000.,
strike=syn_in.strike_1(i),
dip=syn_in.dip_1(i),
rake=syn_in.rake_1(i),
stf=stf,
time=util.str_to_time(syn_in.time_1(i)),
magnitude=syn_in.magnitude_1(i)))
source = CombiSource(subsources=sources)
response = engine.process(source, targets)
synthetic_traces = response.pyrocko_traces()
if cfg.Bool('synthetic_test_add_noise') is True:
from noise_addition import add_noise
trs_orgs = []
calcStreamMapsyn = calcStreamMap.copy()
#from pyrocko import trace
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12])== str(tracex[4:]):
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapsyn[tracex])
tr_org.downsample_to(2.0)
trs_orgs.append(tr_org)
store_id = syn_in.store()
engine = LocalEngine(store_superdirs=[syn_in.store_superdirs()])
synthetic_traces = add_noise(trs_orgs, engine, source.pyrocko_event(),
stations,
store_id, phase_def='P')
trs_org = []
trs_orgs = []
fobj = os.path.join(arrayfolder, 'shift.dat')
xy = num.loadtxt(fobj, usecols=1, delimiter=',')
calcStreamMapsyn = calcStreamMap.copy()
#from pyrocko import trace
for tracex in calcStreamMapsyn.iterkeys():
for trl in synthetic_traces:
if str(trl.name()[4:12])== str(tracex[4:]):
mod = trl
recordstarttime = calcStreamMapsyn[tracex].stats.starttime.timestamp
recordendtime = calcStreamMapsyn[tracex].stats.endtime.timestamp
tr_org = obspy_compat.to_pyrocko_trace(calcStreamMapsyn[tracex])
trs_orgs.append(tr_org)
tr_org_add = mod.chop(recordstarttime, recordendtime, inplace=False)
synthetic_obs_tr = obspy_compat.to_obspy_trace(tr_org_add)
calcStreamMapsyn[tracex] = synthetic_obs_tr
trs_org.append(tr_org_add)
calcStreamMap = calcStreamMapsyn
def calcTTTAdv(Config,
station,
Origin,
flag,
arrayname,
Xcorrshift=None,
Refshift=None):
phasename = ('%sphase') % (os.path.basename(arrayname))
cfg = ConfigObj(dict=Config)
dimX = cfg.Int('dimx')
dimY = cfg.Int('dimy')
gridspacing = cfg.Float('gridspacing')
o_lat = float(Origin['lat'])
o_lon = float(Origin['lon'])
o_depth = float(Origin['depth'])
oLator = o_lat + dimX / 2
oLonor = o_lon + dimY / 2
oLatul = 0
oLonul = 0
o_dip = 80.
plane = False
TTTGridMap = {}
LMINMAX = []
GridArray = {}
locStation = Location(station.lat, station.lon)
sdelta = loc2degrees(Location(o_lat, o_lon), locStation)
Phase = cake.PhaseDef(Config[phasename])
model = cake.load_model()
z = 0
if plane is True:
depth = np.linspace(0., 40., num=dimY)
for i in xrange(70):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
start_time = time.clock()
for j in xrange(40):
oLonul = o_lon - (
(dimY - 1) /
2) * gridspacing + j * gridspacing / np.cos(o_dip)
if o == 0 and j == 0: Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=depth[j] * km,
zstop=0.)
try:
ttime = arrivals[0].t
except:
try:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=depth[j] * km - 2.5,
zstop=depth[j] * km + 2.5,
refine=True)
ttime = arrivals[0].t
except:
tt = obs_TravelTimes(de, o_depth)
for k in tt:
if k['phase_name'] == 'P' or k['phase_name'] == (
'%sdiff') % (Config[phasename]):
ttime = k['time']
print "Something wrong with phase arrival too large\
distances choosen?"
GridArray[(i, j)] = GridElem(oLatul, oLonul, depth[j], ttime,
de)
LMINMAX.append(ttime)
if int(Config['xcorr']) == 1:
ttime = ttime-float(Xcorrshift[station.getName()].shift)\
- Refshift
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
if ttime == 0:
print '\033[31mAvailable phases for station %s in range %f deegree\033[0m' % (
station, de)
print '\033[31m' + '|'.join(
[str(item['phase_name']) for item in tt]) + '\033[0m'
print '\033[31myou tried phase %s\033[0m' % (
Config[phasename])
raise Exception("\033[31mILLEGAL: phase definition\033[0m")
else:
for i in xrange(dimX):
oLatul = o_lat - ((dimX - 1) / 2) * gridspacing + i * gridspacing
if z == 0 and i == 0:
Latul = oLatul
o = 0
for j in xrange(dimY):
oLonul = o_lon - (
(dimY - 1) / 2) * gridspacing + j * gridspacing
if o == 0 and j == 0: Lonul = oLonul
de = loc2degrees(Location(oLatul, oLonul), locStation)
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km)
try:
ttime = arrivals[0].t
except:
try:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km - 2.5,
zstop=o_depth * km - 2.5,
refine=True)
ttime = arrivals[0].t
except:
arrivals = model.arrivals([de, de],
phases=Phase,
zstart=o_depth * km - 2.5,
zstop=0.,
refine=True)
ttime = arrivals[0].t
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
if int(Config['xcorr']) == 1:
ttime = ttime-float(Xcorrshift[station.getName()].shift)\
- Refshift
GridArray[(i, j)] = GridElem(oLatul, oLonul, o_depth, ttime,
de)
LMINMAX.append(ttime)
if ttime == 0:
print '\033[31mAvailable phases for station %s in range %f deegree\033[0m' % (
station, de)
print '\033[31m' + '|'.join(
[str(item['phase_name']) for item in tt]) + '\033[0m'
print '\033[31myou tried phase %s\033[0m' % (
Config[phasename])
raise Exception("\033[31mILLEGAL: phase definition\033[0m")
mint = min(LMINMAX)
maxt = max(LMINMAX)
TTTGridMap[station.getName()] = TTTGrid(o_depth, mint, maxt, Latul, Lonul,
oLator, oLonor, GridArray)
k = MinTMaxT(mint, maxt)
Basic.dumpToFile(str(flag) + '-ttt.pkl', TTTGridMap)
Basic.dumpToFile('minmax-' + str(flag) + '.pkl', k)
Basic.dumpToFile('station-' + str(flag) + '.pkl', station)
def processLoop():
#==================================get meta info==========================================
C = config.Config(evpath)
Origin = C.parseConfig('origin')
Config = C.parseConfig('config')
Meta = C.readMetaInfoFile()
#==================================get meta info==========================================
#==================================do prerequiries========================================
Folder = C.createFolder()
C.cpSkeleton(Folder, Config)
C.writeConfig(Config, Origin, Folder)
cfg = ConfigObj(dict=Config)
filter = FilterCfg(Config)
origin = OriginCfg(Origin)
ntimes = int(
(cfg.UInt('forerun') + cfg.UInt('duration')) / cfg.UInt('step'))
default = 0
strike = origin.strike(default) # Origin.get ('strike', default)
dip = origin.dip(default) # Origin.get ('dip', default)
rake = origin.rake(default) # Origin.get ('rake', default)
# ev = Event (Origin['lat'],Origin['lon'],Origin['depth'],Origin['time'],
# strike = strike,dip=dip,rake=rake)
ev = Event(origin.lat(),
origin.lon(),
origin.depth(),
origin.time(),
strike=strike,
dip=dip,
rake=rake)
filtername = filter.filterName()
Logfile.add('filtername = ' + filtername)
#todo crosscorrelation for all arrays before processing
XDict = {}
RefDict = {}
SL = {}
if cfg.Int('xcorr') == 1:
newFreq = str(filter.newFrequency())
fobjreferenceshiftname = newFreq + '_' + filtername + '.refpkl'
rp = os.path.join(Folder['semb'], fobjreferenceshiftname)
fobjpickleshiftname = newFreq + '_' + filtername + '.xcorrpkl'
ps = os.path.join(Folder['semb'], fobjpickleshiftname)
if (os.path.isfile(rp) and os.path.getsize(rp) != 0
and os.path.isfile(ps) and os.path.getsize(ps) != 0):
Logfile.add('file exits : ' + rp)
Logfile.add('load refshifts')
f = open(rp)
RefDict = pickle.load(f)
x = open(ps)
XDict = pickle.load(x)
#xcorrnetworks = Config['networks'].split(',')
xcorrnetworks = cfg.String('networks').split(',')
for i in xcorrnetworks:
SL[i] = len(Config[i].split('|'))
else:
SL = {}
xcorrnetworks = cfg.String('networks').split(',')
for i in xcorrnetworks:
W = {}
refshift = 0
network = cfg.String(i).split('|')
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
arrayfolder = os.path.join(Folder['semb'], i)
if os.access(arrayfolder, os.F_OK) == False:
os.makedirs(arrayfolder)
A = Xcorr(ev, FilterMeta, evpath, Config, arrayfolder)
W, triggerobject = A.runXcorr()
XDict[i] = W
RefDict[i] = triggerobject.tdiff
SL[i] = len(network)
#endfor
fobjrefshift = open(rp, 'w')
pickle.dump(RefDict, fobjrefshift)
fobjrefshift.close()
output = open(ps, 'w')
pickle.dump(XDict, output)
output.close()
#endif
for i in sorted(XDict.iterkeys()):
Logfile.red('Array %s has %3d of %3d Stations left' %
(i, len(XDict[i]), SL[i]))
logger.info(
'\033[31mFor proceeding without changes press enter or give new comma seperatet network list or quit for exit\033[0m'
)
while True:
nnl = raw_input("please enter your choice: ")
#Logfile.add ('Choise = ' + nnl)
if len(nnl) == 0:
if not Basic.question('Process all networks ?'): continue
Logfile.red('This networks will be used for processing: %s' %
(Config['networks']))
break
elif str(nnl) == 'quit':
sys.exit()
elif str(nnl) == 'rerun':
event = os.path.join(*evpath.split('/')[-1:])
try:
os.remove(rp)
os.remove(ps)
except:
pass
mainfolder = os.path.join(os.path.sep, *evpath.split('/')[:-2])
os.chdir(mainfolder)
cmd = ('%s arraytool.py process %s') % (sys.executable, event)
Logfile.add('cmd = ' + cmd)
os.system(cmd)
sys.exit()
else:
# Check if selected array(s) exists
names = nnl.split(',')
isOk = True
for array in names:
arrayfolder = os.path.join(Folder['semb'], array)
if not os.path.isdir(arrayfolder):
Logfile.error('Illegal network name ' + str(array))
isOk = False
break
#endfor
if not isOk: continue # Illegal network : input again
# use these networks
Logfile.add('This networks will be used for processing: %s' %
(nnl))
Config['networks'] = nnl
break
#endif
#endwhile True
for i in range(3, 0, -1):
time.sleep(1)
Logfile.red('Start processing in %d seconds ' % (i))
#endfor
#print XDict
#print RefDict
#TriggerOnset.append(triggerobject)
#print 'MAINTDIFF ',triggerobject.tdiff
#sys.exit()
wd = Origin['depth']
start, stop, step = cfg.String('depths').split(',')
start = int(start)
stop = int(stop) + 1
step = int(step)
Logfile.add('working on ' + Config['networks'])
#==================================loop over depth=======================================
for depthindex in xrange(start, stop):
workdepth = float(wd) + depthindex * step
Origin['depth'] = workdepth
ev = Event(Origin['lat'],
Origin['lon'],
Origin['depth'],
Origin['time'],
strike=strike,
dip=dip,
rake=rake)
Logfile.add('WORKDEPTH: ' + str(Origin['depth']))
#==================================do prerequiries========================================
#==================================loop over arrays=======================================
ASL = []
networks = Config['networks'].split(',')
counter = 1
TriggerOnset = []
for i in networks:
arrayname = i
arrayfolder = os.path.join(Folder['semb'], arrayname)
network = Config[i].split('|')
Logfile.add('network: ' + str(network))
FilterMeta = ttt.filterStations(Meta, Config, Origin, network)
#if len(FilterMeta) < 3: continue #hs : wieder rein
if len(FilterMeta) < 3: continue
W = XDict[i]
refshift = RefDict[i]
FilterMeta = cmpFilterMetavsXCORR(W, FilterMeta)
#print 'W: ',W,len(W); print refshift; print 'FM ',FilterMeta,len(FilterMeta)
Logfile.add(
'BOUNDING BOX DIMX: %s DIMY: %s GRIDSPACING: %s \n' %
(Config['dimx'], Config['dimy'], Config['gridspacing']))
##############=======================PARALLEL===========================================
Logfile.red('Calculating Traveltime Grid')
t1 = time.time()
if WINDOWS:
isParallel = False #hs : parallel
#else : isParallel = True #10.12.2015
else:
isParallel = False #10.12.2015
if isParallel: #hs
maxp = int(Config['ncore'])
#maxp = 20 #hs
po = multiprocessing.Pool(maxp)
for i in xrange(len(FilterMeta)):
po.apply_async(ttt.calcTTTAdv,
(Config, FilterMeta[i], Origin, i,
arrayname, W, refshift))
po.close()
po.join()
else: #hs+
for i in xrange(len(FilterMeta)):
t1 = time.time()
ttt.calcTTTAdv(Config, FilterMeta[i], Origin, i, arrayname,
W, refshift)
Logfile.add('ttt.calcTTTAdv : ' + str(time.time() - t1) +
' sec.')
#endif #hs-
assert len(FilterMeta) > 0
TTTGridMap = deserializer.deserializeTTT(len(FilterMeta))
mint, maxt = deserializer.deserializeMinTMaxT(len(FilterMeta))
t2 = time.time()
Logfile.red('%s took %0.3f s' % ('TTT', (t2 - t1)))
#sys.exit()
##############=======================SERIELL===========================================
tw = times.calculateTimeWindows(mint, maxt, Config, ev)
Wd = waveform.readWaveforms(FilterMeta, tw, evpath, ev)
Wdf = waveform.processWaveforms(Wd, Config, Folder, arrayname,
FilterMeta, ev, W)
#sys.exit()
C.writeStationFile(FilterMeta, Folder, counter)
Logfile.red('%d Streams added for Processing' % (len(Wd)))
##############=========================================================================
##############=======================PARALLEL==========================================
t1 = time.time()
arraySemb = sembCalc.doCalc(counter, Config, Wdf, FilterMeta, mint,
maxt, TTTGridMap, Folder, Origin,
ntimes)
t2 = time.time()
Logfile.add('CALC took %0.3f sec' % (t2 - t1))
ASL.append(arraySemb)
counter += 1
sembCalc.writeSembMatricesSingleArray(arraySemb, Config, Origin,
arrayfolder, ntimes)
fileName = os.path.join(arrayfolder, 'stations.txt')
Logfile.add('Write to file ' + fileName)
fobjarraynetwork = open(fileName, 'w')
for i in FilterMeta:
fobjarraynetwork.write(
('%s %s %s\n') % (i.getName(), i.lat, i.lon))
fobjarraynetwork.close()
if ASL:
Logfile.red('collect semblance matrices from all arrays')
sembCalc.collectSemb(ASL, Config, Origin, Folder, ntimes,
len(networks))
#fobjtrigger = open (os.path.join(Folder['semb'],'Trigger.txt'),'w')
#for i in TriggerOnset:
# print i.aname,i.sname,i.ttime
# fobjtrigger.write(('%s %s %s\n')%(i.aname,i.sname,i.ttime))
#fobjtrigger.close()
else:
Logfile.red('Nothing to do -> Finish')
